Plural Element Composite Materials, Methods for Making and Using the Same

ABSTRACT

The invention provides composite materials comprising a shape change element and an optical change element, which elements undergo a change in response to an applied stimulus. Also provided are objects that include the subject shape changing materials, as well as methods of making and using the same.

CROSS-REFERENCE To RELATED APPLICATIONS

Pursuant to 35 U.S.C. §119 (e), this application claims priority to thefiling date of U.S. Provisional Patent Application Ser. No. 60/504,180filed Sep. 17, 2003; the disclosure of which is herein incorporated byreference.

INTRODUCTION Background of the Invention

Composite materials are structures or entities that are made up ofdistinct components. A variety of different types of composite materialshave been developed and employed in a multitude of different and diverseapplications. Because of utility of composite materials, there continuesto be an interest in the development of new composite materials.

Relevant Literature

See e.g., U.S. Pat. Nos. 4,950,258; 5,665,822; 5,918,981; 6,465,791;6,612,739; 6,669,444; 6,675,610; 6,740,094; 6,759,481; 6,720,402;6,790,395; and 6,790,916.

SUMMARY OF THE INVENTION

The invention provides composite materials comprising a shape changeelement and an optical change element, which elements undergo a changein response to an applied stimulus. Also provided are objects thatinclude the subject shape changing materials, as well as methods ofmaking and using the same.

As such, embodiments of the invention involve plural intrinsic compositematerials which possess and combine shape, memory, and structurallyconforming compositions with a plurality of independent color changingand/or optical shifting compositions such as thermochromic,photographic, photochromic, tactochromic, solvate chromic, pH sensitiveindicating chromic change agents, photo-luminescent materials,iridescent materials, birefringence materials, optical waveflightguiding and/or related materials. The plural intrinsic compositecompositions are capable of simultaneously or sequentially undergoingshape and optical/visual changes uniquely and in pre-determined formats.The comprising compositions and embodiments can sense, report, andrespond to environmental conditions they are exposed to.

The plural composite shape/memory/color optical shifting/changingmaterials exhibit novel multiple effects of simultaneously or with apredetermined historesis, changing shape in response to an environmentalparameter such as temperature while also instantaneously changing itsoptical characteristics. The combined shape and optical shiftingelements provides for new and unusual features, characteristics,effects, usage, play-value, novelty, and utility compared with eithersingularly color changing materials or shape changing materials.

DESCRIPTION OF THE SPECIFIC EMBODIMENTS

The invention provides composite materials comprising a shape changeelement and a optical change element, which elements undergo a change inresponse to an applied stimulus. Also provided are objects that includethe subject shape changing materials, as well as methods of making andusing the same.

Before the present invention is further described, it is to beunderstood that this invention is not limited to particular embodimentsdescribed, as such may, of course, vary. It is also to be understoodthat the terminology used herein is for the purpose of describingparticular embodiments only, and is not intended to be limiting, sincethe scope of the present invention will be limited only by the appendedclaims.

Where a range of values is provided, it is understood that eachintervening value, to the tenth of the unit of the lower limit unlessthe context clearly dictates otherwise, between the upper and lowerlimit of that range and any other stated or intervening value in thatstated range, is encompassed within the invention. The upper and lowerlimits of these smaller ranges may independently be included in thesmaller ranges and are also encompassed within the invention, subject toany specifically excluded limit in the stated range. Where the statedrange includes one or both of the limits, ranges excluding either orboth of those included limits are also included in the invention.

Methods recited herein may be carried out in any order of the recitedevents which is logically possible, as well as the recited order ofevents.

Unless defined otherwise, all technical and scientific terms used hereinhave the same meaning as commonly understood by one of ordinary skill inthe art to which this invention belongs. Although any methods andmaterials similar or equivalent to those described herein can also beused in the practice or testing of the present invention, the preferredmethods and materials are now described.

All publications mentioned herein are incorporated herein by referenceto disclose and describe the methods and/or materials in connection withwhich the publications are cited.

It must be noted that as used herein and in the appended claims, thesingular forms “a”, “an”, and “the” include plural referents unless thecontext clearly dictates otherwise. It is further noted that the claimsmay be drafted to exclude any optional element. As such, this statementis intended to serve as antecedent basis for use of such exclusiveterminology as “solely,” “only” and the like in. connection with therecitation of claim elements, or use of a “negative” limitation.

The publications discussed herein are provided solely for theirdisclosure prior to the filing date of the present application. Nothingherein is to be construed as an admission that the present invention isnot entitled to antedate such publication by virtue of prior invention.Further, the dates of publication provided may be different from theactual publication dates which may need to be independently confirmed.

As summarized above, the invention provides composite materials thatinclude a shape change component and a color change component, as wellas articles that include the subject composite materials and methods formaking and using the same. In further describing the various aspects ofthe invention, the composite materials are reviewed first in greaterdetail, followed by a discussion of representative articles and methodsof use thereof.

Color shifting/changing materials can include but are not limited tophoto-luminescent material such as glow-in-the dark iron complexes,polydiacetylenes, polythiophenes, leuco-dyes, stilbene compounds,mercury complexes, melting waxes, encapsulated dyes, liquid crystallinematerials, spyrene materials, mercury salt dyes, tin complexes,combination thermochromic/photochromic materials, photochromic agents,glow-in-the-dark materials such as zinc sulfide which has been copperdoped, birefringent materials, shimmer materials such as those used incosmetics, holographic mediums or holographic printed materials, heatformable materials which change structure based on temperature, naturalthermochromic materials such as pigments in beans, piezochromic dyes,tribochromic dyes, photoconducting dyes, dyes used for organic lightemitting diodes, or any acceptable thermochromic materials with thecapacity to report a temperature change or can be photo-stimulated andthe like.

Shape/memory materials with intrinsic optical properties can exhibit aplurality of shape/memory changes combined with single or multipleoptical effects including but are not limited to thermochromic,photochromic, combined tactochromic and thermochromic effects, combinedholographic and thermochromic effects, combined thermochromic andphotochromic effects, combined photo-luminescent and thermochromiceffects, various combined thermochromic effects such as liquid crystaleffects and intrinsic color change effects from polydiacetylenes oralternative thermochromic materials, mechanochromic and thermochromiceffects, pH sensitive color changes alone or in combination with otheroptical effects, and an assortment of related combined optical effectswhich exhibit synergy with the shape/memory change process.

Colloidal diacetylene compositions are readily polymerized using thermalpolymerization and UV photopolymerization. The resulting polymer remainsvery stable in a broad range of organic and aqueous solvents. Thethermochromic temperature transition shows robust thermochromicreversibility in a wide variety solvent systems including harsh organicsolvents such hexane, chloroform, acetone, ethanol and the like. Thethermochromic transition is dictated by the fatty acid chain link. Chainlinks form C8 fatty acids through C40 fatty acids with a diacetylenemoiety which have been synthesized, dymerized and polymerized.Thermochromic transitions have been obtained with pure dymerizedPolydiacetylene polymers as well as plural compositions where thediacetylene polymer has been mixed with a thermally responsivecomposition such as paraffin, waxes, block co-polymers, plastics,silicon rubbers and the like. The plural intrinsic compositions showexcellent stability, thermal reversibility, and manufacturing processingcapabilities.

Refractive index shifting and iridescent materials and birefringentmaterials can be used as additives to the shape/color change embodiment.Thin mica and glass particles can be used to create a shimmering effectduring the shape changing process.

Holographic films, stamps, labels, inclusions or layers can belaminated, adhered, or incorporated into the shape/memory material tocreate further novel optical effects during the shape/memory changeprocess. Physical shape change effects combined with optical refractiveindex change effects can be used to create new and unexpected animationeffects with out physical contact. The shape change will transmit anintended holographic change effect when the change occurs. The effectcan be localized or transmitted throughout the embodiment. Theholographic effect can correlate with the actual physical shape/memorychange or be used to create unexpected and entertaining optical effectsduring the shape change/shape memory process.

Translucent holographic images embedded in shape memory material throughdirect heat lamination, using heat or cold laminating films, be directlyimprinted into the shape/memory material, be introduced or printed intoto the material using laser etching techniques, adhered to the surfaceusing pressure sensitive adhesive materials, be stamped using dyestamping holographic labeling techniques, roll pressed onto thematerial, cast or hot pressed, hot stamped directly on indirectly ontothe material or the like.

Shape/memory/optical materials can be utilized in novel formats tocreate flexible displays which eliminate the limitations of flat-screendisplay devices. For example, Flat panel display components used forcomputer and electronic devices are restricted to a planarconfiguration, in a square or rectangular format. Integratingshape/memory materials can be used to comprise interconnections betweendisplay components such that the display can be flexibly changed toassume non-planar shapes. By way of example, a liquid crystal oralternative display can be designed with interconnects to fold into acube or geodesic structure. Icosahedral geometries can be generatedusing discrete hexagonal and pentagonal segmentations. Display panelscould thus be folded, unfolded, and utilized in a variety of geometriesdepending on the application of interest. Triggering of the shape/memoryprocess can be induced using integrated heating elements in contact withthe shape/memory material such that a pre-determined shape can beassumed upon engaging the appropriate voltage to initiate electricallyconductive heating.

Shape/memory/color change adhesives can be employed where acharacteristic glue or adhesive can be made to simultaneously changeshape/properties and/or color. In particular, polydiacetylenic pigmentsor other thermochromic agents can be formulated along with an adhesivecomponent which has a temperature dependence on its adhesivecharacteristics or strength.

Particle additives of a variety of shapes and sizes can be combined withthe shape/memory material to create attractive and interesting visualaffects during the shaping, deformation, reshaping or shape memoryprocess. Glitter as an additive can be comprised of metalized film,iridescent film, metal particles, thin iridescent glass flakes, andvarious colored plastic film particles. Other particle additives caninclude lake dyes of various colors, refractive index matchingparticles, fluorescent particles, fluorescent micro-beads, magnetic andparamagnetic particles, optically polarized particles and films

Depending on the shape/memory material composition and associatedoptical/change composition employed, it may be desirable to ensure thecomprising composition does not stick or adversely adhere to itselfduring use. Lubricating agents or surfactants can be employed tofacilitate non-stick or adherence properties. By way of example,shape/memory color change filaments used for artificial hair can betreated with standard hair conditioner to mitigate tangling andfacilitate detangling during the shaping process.

Self-configuring or morphological changing embodiments can be generatedusing shape/memory/optical changing compositions. For example, a flat ordeformed layer comprised with shape/memory and/or color shiftingmaterials can assume an initial shape. The shape/memory component cancontain a relief material or additive which harbors an intrinsic shapepre-set in the composition. Upon warming, object will assume its firststate or configuration (e.g. a factory molded toy configuration).

Woven fabrics comprising shape/color shifting composites can be preparedusing standard fabric weaving process, knitting process, sewingprocesses and the like. Woven or fabric forms of shape/memorycompositions and shape/memory compositions integrating color/opticalchange materials can be used in garments, swimwear, toy or dollclothing, footwear, military garments, exercise wear and garments,indoor and outdoor sporting garments, patches, padding, costumes andrelated embodiments where it is desired to have a temperature dependentshape/memory change and/or color shift associated with usage.

Fiber optics and optical wave guides can also be incorporated into theshape/memory changing material such that the optical properties andeffects comprising the fiber optical and/or wave guide material can bepreserved even though the composite embodiment may undergo a significantstructural or shape change. For example, a series of thin fiber opticstrands may be positioned in parallel along the plane of a shape/memorycomposite. The strands may be laminated of embedded into theshape/memory material such that only the beginning and ends are free andun-embedded. Light may be transmitted into the optical fibers from oneend and emitted from the other end. As the shape memory material istransitioned from one shape to another, the illuminating light patternfrom the emitting end can be made to change its pattern and form. Uniqueoptical effects can be achieved from the emitted light pattern.

By way of further example, hair on a doll may be comprised of a fiberoptic internal core along the length of the strand. The fiber opticstrand may be coated with an outer sheath of shape memory material suchthat each end of the hair strands expose both ends of the fiber opticinternal core.

Fiber optic and wave guide materials may be selected to possess both thelight guiding properties of guiding and directing light and as a reliefmaterial which provides the embodiment with incremental force forresuming an initial shape.

Miniature light emitting diodes and associated circuits can be includedor imbedded within the plural composite such that the led will go on oroff depending on the shape or shape change of the embodiment ofapplication. The led may begin flashing when a certain shape is assumed.

A multiplicity of plural shape and optical effects can also be achievedby incrementally adding one or more color change and other opticallyrecognizable components. For example, a shape memory material can beadmixed with a thermochromic material as well as a refractive indexchanging material such as micro-particulate mica. Theshape/color/optical effect can be sequential. Initially, the comprisingcomposition will have a starting color and shape below the softeningtemperature of the shape/memory material. Likewise, the opticalrefractive index of the micro-particulate mica will have an initialvisual reflectivity. As the temperature is increased, the color changeof the thermochromic material can be selected to change first. The shapechange of the shape/memory change material can be set to change second.Upon the final shape change and during the shape changing process, thereflectivity of the micro-particulate material will subsequently change.The sequential effect give rise to a continuum of physical and opticaleffects. Likewise, the effects can be reversed upon cooling and/orreheating and reshaping and subsequent return to the initial shape andstarting temperature.

The plural composite materials can be co-formulated, co-extruded,co-mixed, laminated together, painted or coated, printed, fused, or thelike to make the desired output. Injection molding process can be usedto conveniently mold high volume applications with well defined initialconfigurations. Sheet extrusion and forming can be used to create flatwell defined sheet thicknesses and textures. Filament extrusion anddrawing can be conveniently used to create thin strands and hair-likethicknesses and properties. Blow molding can be used to create cavitatedmolded forms such as three dimensional enclosures. Thermoforming can beused to create cavitated open three dimensional embodiments. Pressuremolding and forming can be used to create simple solid forms. Any of avariety of forming and molding techniques can be used to form initialshapes for the shape/memory color change plural composites.

Shape-memory plastics can be deformed from 1% to 500%. More usually theydeform from 10% to 400% and typical applications call for deformationfrom 100% to 300%. The degree of desired deformation will depend on theapplication of interest and the capabilities of the shape/memorycomposition selected for a particular embodiment.

The shape memory changing composite can be formulated for varioustemperature effects and temperature settings from=50° F. to hightemperatures above about 500° F. In representative embodiments, thedesirable shape/memory change is formulated to be set between about 10°F. and about 300° F. In representative embodiments, the temperature willbe set between about 32° F. and about 200° F. and more usually betweenabout 50° F. and about 130° F.

Shape/memory material can be purchased from vendors such as BASF,DuPont, Bay Materials or the like. Shape/memory composites can be madewith shape/memory plastics, vinyl, high and low impact plastics exoticpolymers used for various industrial applications, epoxy resins wherevarious ratios between the epoxy and hardener can be utilized, metalsand metal alloys, bi-metal materials used in thermometers, comprisedwith components including rubbers, silicon-based materials, certainceramic materials, pressure sensitive material, stampable materials,biologically compatible materials, carbohydrate based materials, organiclipophilic materials, waxes, biologically active materials, certaintissues such as muscle, skin or hair, bio-absorbable materials, glasscompositions, ingestible materials, resins, epoxy-based composites andresins, glue and adhesive compositions, polyurethanes and derivatives(Mitsubishi Heavy Industries, Japan), shape memory alloys, shape-memoryplastics (mnemoScience, Aachen, Germany), oligo-dimethacrylate,n-butylaerylate and related polymeric plastics, thermoplasticelastomers, networking polymeric systems, classes of polyesters,polymers based on monomers comprised with L,L-dilactide, diglycolide,and p-dioxanone, thermoplastic multi-blockco-polymers, macrodiols,homopolymers of lactide or glycolide compositions, or copolymers oflactide and glycolide groups, chiral and non-chiral polymers, polyvinylchloride compositions, polyethylene terephthalate and analogs, andrelated materials possessing shape/memory characteristics.

Foam-based compositions can be formulated where closed or open cellcompositions comprise a rigid configuration at lower temperatures and aspongy pliable foam-like configuration at elevated temperatures. Theshape-changing composition can be foamed with air by means of airinclusion during mixing, differential pressure injection, addition offoaming agents (e.g. those used for injection molding), and the like.Shape changing compositions can contain from 0% air to 90% air dependingon the application of interest.

Foam-based compositions have the advantage of providing increased volumean a per pound cost basis. Foam-based compositions can be used forvarious toy and game applications where the spring-back of encapsulatedair provides an array of play and molding options. Foam-basedcompositions can be used as temperature dependent actuation means wherea compressed foam does not expand until a certain temperature isachieved. When a desired temperature is achieve, the compositionmaterial re-orients to a desired dimension.

Air pocketed laminates can be prepared such as those used in packagingmaterials. Air pocketed laminates can be prepared by laminatingperiodically dimpled sheets of shape-changing materials together suchthat the dimpled regions entrap a desired amount of air. Pressure heatsealing can be used as a means for laminating a top layer to a bottomlayer. Air can be hermetically sealed in the process. Air pocketedlaminates can find a variety of utilities and uses. Color/shape/memoryair pocketed laminates can be used for modeling, forming and free playfor children. Like-wise, air pocketed laminates can be used forpackaging and retaining items to be shipped. In the warmed state aboveambient shipping conditions, the laminate can be used to precisely fitaround an object. When cooled, the laminate will form a snug solid fitaround the object for shipping. The process can be reversed to releasethe object once it has been delivered.

Organic polymeric groups can range in molecular weight from less thanabout 1000 g/mol to more than about 10,000,000 g/mol. The shape/memoryplastic selected, polymer composition and degree of polymerization willdepend on the application of interest.

The shape changing material may be comprised by a composition whichreversibly changes from one configuration to another and back again,irreversibly changes from one configuration to another and remains inits final shape, or can be formulated to possess intrinsic abilities toundergo various permutations with and without having memory of itsinitial or final configuration.

The absolute shape/memory change setting will depend on the productapplication of interest. For example bath toys have been prepared whichchange color and shape/color when warmed to about 100° F. At roomtemperature or below, the toy will have a solid plastic-like feel. Thecolor or hue can be adjusted to correspond to a desired visualattractiveness for the toy. When the toy is touched, or exposed totemperatures near body temperatures (e.g., 75-90° F.) the correspondingcolor and shape will begin to change. The plastic embodiment will becomesoftened and begin to deform. Likewise, the thermochromic materialcomprising the composition along with the shape/memory plastic willvisually change color corresponding to the rise in temperature. Whencompletely warmed above the softening temperature of the shape/memorymaterial, the toy will be completely deformed to whatever configurationdesired. When chilled back to room temperature or below, the plasticshape/color change embodiment will harden into its deformedconfiguration. Likewise, the toy will change color reversibly backReversible and irreversible versions of the color change agent can beemployed depending on the desired embodiment of interest. Reversibleagents can be employed where it is desirable to have a multi-use effector reuse the color change effect. For example, toy products withcontinued and repeated play value will find use of a reversible colorchange component comprising the final embodiment. In this case it wouldbe desirable to utilize a reversible thermochromic or luminescentmaterial which can be repeated during usage. In another example, it maybe desirable to record a single color change permanently. In this case,it would be desirable to utilize a thermochromically irreversiblematerial which changes from one color to another giving rise to apermanent massage.

Shapes can be made to change slowly or with rapid response time byadding relief layer composites, embedded springs, flexible stays, orrelief additives. The relief layer or additive acts to accentuate ashape/memory effect. For example, a stiffened plastic thread can becoated with a shape memory material whereby the coating will be moldableat a temperature setting. Once molded and chilled to set the desiredshape, the fixed shape strand will hold its configuration until it iswarmed above the softening temperature of embodied composition. Thesoftened shape/memory material will permit the stiffened plastic threadto resume its original structure and extend to its original position.

The shape/memory material and associated relief layer material can beformulated with 95% relief material to 5% shape/memory material. Moreusually with 50% relief material and 50% shape/memory material.Typically the shape/memory material will comprise from 60 to 100% of thecomposition. The exact ratio of shape/memory material to relief materialwill depend on the desired final property of the embodiment orapplication of interest. The configuration, shape/memory composition,relief composition, and method for adjoining each component should beconsidered when designing the final embodiment.

The shape/memory/optical material can be comprised with an elastomericmaterial such that the elastic properties of the elastomer can beutilized to create spring or rubber band-like function. An associatedelastomer can be stretched along with the entire comprising compositionabove the softening temperature of the shape/memory material. A shapecan be enforced once the composition is made stiff at below thesoftening temperature of the shape/memory/optical material. Uponelevating the temperature of the composition above the softening and/oroptical change transition temperature, the entire composition willrespond elastically to its original configuration and optically visualappearance.

The shape/memory/optical material can be comprised as above with aflexible metal or plastic spring such that the spring will facilitatethe conformational changes that the plural intrinsic compositeundergoes. Any of a variety of other flexible, semi-rigid, elastomeric,load bearing, torsion bearing, friction bearing, or related materialscan be employed as a facilitating means to impose initial and finalconformations on the plural intrinsic shape/memory/optical changecomposition. By way of example, a sponge-like foam can be coated orcontained within the shell of a shape/memory/optical change materialsuch that a shape can be imposed and solidified by heating and coolingin an intended shape. Subsequent heating and softening will causereformation to the initial molded shape assisted by the spring actionfrom the entrapped foam lattice.

Similar compositions of the thermal switching/responsive material incombination with a color-shift reporting element provides for a newcomposition with intrinsic capabilities of both changing its physicalproperties such as solid to liquid phase transition, viscosity,hardness, and related physical parameters as well as a change in itsvisual color appearance characteristics such as color hue, colordensity, opacity, and related optical characteristics. These pluralcompositions have multiple applications in areas including adhesives,medical implants, industrial compositions for engineering andelectronics, game applications for new color-shifting toys, materialsapplications for new building compositions including household andcommercial applications, as well as other retail commercial andindustrial applications.

Temperature changes can be introduced with water, air, electricallyconductive circuits, heat lamps, radiating heat sources, microwaveheating where the shape/memory material has a microwave reactivecomponent present, frictional heat induction, chemically inducedheating, laser optically induced heating, semiconductor laser opticallyinduced heating, resistive heating elements, Peltier plate inducedheating, fluid circulating heating sources, solar heating, directed oropen flames, burning rocket propellant, various forms of contact andconductive heating, heating body contact and the like.

Electrically conductive heating elements can be employed whereconductive and/or resistive heating inks are printed into various orspecific patterns to achieve a desired localized or patterned heatinglocation on the embodiment.

The shape/memory and/or color change materials will comprise from 0.01%to 100% of the embodiment. More usually, the shape/memory and/or colorchange materials will comprise from 0.1 to 100% and typically comprisefrom 1% to 100%.

The final embodiment can be comprised with localized portions of theshape/memory and/or color change comprising material such that hinges,localized deformations, bends, protrusions, bulges, patterns, designs,extensions, and the like can be effected whereas the remaining portionof the final embodiment is unaffected by the shape/memory and/or colorchange process.

Shape/memory materials can be comprised with inert plastics, strainedwood, polymeric composites, foods, lift-off layers adhered to foodlayers whereby the food will change shape when the shape/memory materialchanges shape. For example, a sugar layer, edible paper layer, fondantlayer or the like can be coated on a thermally responsive shape/memorymaterial. The edible layer can be plain or colored with food color.Alternatively, the edible layer can be printed using a screen printingor ink jet printing method to create a graphic image, pattern, messageor the like. When the laminate is exposed to heat, the shape/memorymaterial will correspondingly change shape to a desired configuration.Graphics printed on the edible layer can be initially generated suchthat they are accurately displayed after the shape change has occurred.Prior to the shape change, the graphic may be confused, scrambled, ordistorted. The shape/memory change process provides an attractive meansto create new interactive food groups.

The color change or optical change agent can be formulated to conform toa desired color change at a predetermined temperature setting. The twoeffects, including shape and/or color change, can work synergisticallyto achieve a desired product effect. The temperature settings for colorand shape change can be designed into the embodiment of interest suchthat the color and shape change occur at the same temperature ordifferent temperatures. It may be desirable for the color change tooccur prior to the shape change during the temperature elevationprocess. Alternatively, it may be desirable for the shape change toprecede the color change during the temperature elevation process.

Agents used for the color or optical change process can have an abruptcolor change within 1 to 2 degrees centigrade or can have hue changecontinuum over a substantially larger temperature range. Color changescan be formulated to occur from within about 0.1° F. to about 400° F.range, including from about 1° F. to about 200° F. range, and such aswithin a 5° F. to 100° F. range.

The shape/memory composite may be transparent, opaque, or have apre-determined level of opacity. The composite my have non-changingcolors or stationary colors added to create pre-determined initialcolorations. Single or multiple color changes and/or hue changes can beutilized such that the color change can reflect different temperatureachieved as well as different physical states for the shape/memorymaterial being employed.

Plural intrinsic shape/memory/optical shift compositions find use in toyapplications where the toy is played with, warmed or cooled and theresulting toy changes both shape and color, games, dolls, dollcomponents, toy and doll accessories, re-sizable and reshapeable actiontoys, indoor and outdoor toys, bath toys, arts and crafts applications,transient molding materials for making temporary molds, personnel careproducts, temperature monitoring devices, house-hold products,appliances, packaging materials, industrial monitoring devices, switchesand fuses, child safety products, sterilization indicators, cookingdevices, reusable thermometers, physiologic thermometers, processcontrol monitors, athletic equipment, medical devices such heart stintsand catheters which require a shape change or expansion which can bereversed, merchandise displays, adhesive mechanisms, swimming poolaccessories, beverage bottles, collapsible containers for food storageand general storage, cook ware utilizing a desired elevated color/shapechange, moldable athletic equipment such as skis, swimming gear,moldable personnel accessories such as jewelry, eye ware, head and footgear which can be reconfigured or shaped for different purposes, tubingand piping for gas and liquid flow which indicates flow where flow isaffected by temperature, exercise training gear where stiffening orsoftening can be regulated to increase or decrease physical exertion,battery testing devices where power levels can be indicated by both ashape and optical change, fire safety devices, and the like.

Various shapes and colors can be pre-set for various applications. Fortoys, it is desirable to use color/shape changing plural compositeswhich shift color and shape under physiologic or close to ambientconditions that would normally be encountered during toy play. Examplesinclude indoor and outdoor play, bath toys with warm and cool watereffects, swimming pool toys, toys with mild heating elements or lightheating ovens for induced heating.

For certain toy, game, craft, entertainment, operations, prototyping,and related applications, it will be desirable to utilize a mold fixturedevice in combination with the shape/memory/optical change material tocreate well defined structured, featured, patterned, shaped, contoured,or three-dimensional objects. For example, toy manufactures couldprovide and sell both the shape/memory/optical change material in asheet form as well as a simple to use molding station to create funshape/color changing designs, patterns, play figures, dolls, actionfigures, toy trucks or cars, heads, toy robots and/or parts, toyairplanes, learning pieces, 3-d puzzle pieces, hats, dishes, cups,building pieces, animal or bird shapes, flower or insect shapes or anyof an unlimited variety of toy examples.

The shape/memory/color changing kit could include pre-cut pieces ofshape/memory/color change sheets. The sheets could be plain orpre-printed and die cut. Printed varieties could include images whichappear flattened and distorted until molded into the designated orintended shape. Die cut patterns or shapes could include score marks,relief lines, and cuts intended to facilitate the molding and contouringprocess. The pre-cut pieces could be sized according to the manufacturesspecifications to be used with a molding station.

The molding station can comprise a means by which a pre-cut sheet can beinserted into an insert zone. The insert zone would help to orient thesheet. A shaping or molding form could be positioned below the sheetinsert zone and a conforming upper mold form similarly shaped to thelower form could be positioned immediately above the sheet insert zone.The configuration provides a means to form a sandwich including theupper form, the shape/memory/color changing sheet, and the lower moldform. The system can provide a means to rapidly heat the sheet, sandwichand compress the sheet from a planar two-dimensional shape to acontoured three-dimensional shape, and a cooling means by which tosolidify the shape/memory/color change material into a desired design.

The molding station can be designed in different ways to use hot and/orcold air, hot and/or cold water, radiant heat along with a coolingmeans, or any of a variety of cost effective and reliable heating andcooling means depending to the various applications of interest. Themolding station can also come with easy to remove and replace upper andlower molding forms such that different objects can be shaped asdesired. This configuration provides the manufacturer with an on-goingsource of extending the product line.

Objects such as toys or crafts items can be shaped, annealed andsolidified into designated forms and kept that way for use orre-flattened and shaped by a person using the system. Toys, for example,could be formed, played with, and then flattened again for storage.

Embodiments can include electrically conductive heating elements forinducing the heating/shape/color change. The electrical conductivecircuit can be oriented on the embodiment or application of interestsuch that the circuit provides heat when a voltage is supplied; theapplied heat results in a temperature necessary to induce a color andshape change in the toy. Conducting materials for creating integratedpre-determined heating elements include silver conducting inks andpastes, metal based inks, carbon based inks, inks containing indium tinoxide as a conductive material or the like.

Heating elements can be adhered, contacted, stamped, etched, appliedusing photo lithography, vapor deposited, coated, extruded, laminated,pressure sensitively applied, taped, painted, molded, sprayed, screenprinted, pad printed, flexo graphically printed, Gravier printed,off-set printed, flood printed, or applied by any convenient meanscompatible with a production process.

Sensing elements such as piezo-electric devices and substrates, radiowave frequency devices (passive and active) where shape andconfiguration can be used to modulate reception or transmission, straingauges, thermocouples, resonating devices, receiving and transmittingdevices, galvanic monitoring elements, and microelectronic devices.

Foamed forms of the shape/memory/optical shifting/changing compositionscan be prepared such that the composite is in a Styrofoam-likeconfiguration. Foamed forms of the composite can be made using standardfoaming/forced air methods.

Hard solid/softened pliable, hard solid/liquid molten, softenpliable/liquid molten, hard solid stretch/softened relaxed, and a widerange of convenient forms can be utilized for various productembodiments which require specific characteristics and properties.

A wide variety of combinations and permutations of shape changingplastic/optical component additives can be utilized for varying productapplications. Single optical agents can be used alone with a shapechanging plastic or in combination with one or more additional selectiveoptical agents. A wide range of plural property changes can be derivedthat can be engineered to occur simultaneously or sequentially.

Shape memory polymers can include polynorborene, polyisoprene, styrenebutadiene, and polyurethane-based materials and vinyl acetate, andpolyester-based compounds. A variety of formulations and derivations canbe compounded. Exemplary polyethylene and polypropylene vinyl acetates(Du Pont Corporation, Atofina Corporation, Canada) can be used as fillercompositions, to add rubber-like characteristics, to add elasticity, toincrease or decrease transition temperatures and the like. Polyethyleneand polypropylene vinyl acetates are readily mixed into a wide range ofcompositions (300° F. or below).

By way of example, but not limitation, base thermoplastic polyurethanes,polyesters, and related compositions typically used for laminationadhesives and coatings (Mor-Ester™ 49000-P polyester, Rohm And HaasCorp., Estane™ solution and hot melt applications compositions including5703, 5719, 5714, 5701, 5708, 5714, 5707, 5715, and 5778, and Tecothane™aliphatic compound OP series OP600 (Noveon Corp.) can be used as basematerials for low temperature shape-changing plastics.

Capero-lactones, and related thermoplastics that have putty-likecharacteristics at moderately high temperatures (e.g. Protoplast™, WFRAquaplast Corp.) and gum bases that have putty-like characteristics atlower temperatures (e.g. Dreyco base and related gum bases, L. A.Dreyfus Corp.) can be used as starting materials for high temperature(140° F. or greater) and low temperature putty bases (140° F. or lower).

Polymer compositions can be further cross-linked for increasedtemperature settings, durability, structural strength, and relatedproperties which can impart a desired effect on the polymer's structureand character. Cross-linking, irradiation, repeated heat annealing, andcompounding methods can be utilized.

Thermoplastic compositions that can be used as additive plasticsinclude, but are not limited to: polyvinyl chloride (PVC), variouspolyolefins, such as polypropylene and polyethylene, cross-linkedhigh-density polyethylene (XLPE), softened acrylic, polycarbonate, ABS,thick Kapton™ tape materials, Teflon™ (tetrafluoroethylene TFE andfluorinated ethylene polypropylene FEP)-based materials, brand namessuch as Kydex, polystyrene, thermoplastic polyesters, nylon,styrene-butadiene, epoxy casts, polybutylene, TPX (poly(methyl pentene),PETE, PETF, polyethylene teraphthalate G copolymer (PETG), polysulfone(PSF), polyutethane (PUR) Thermanox™ (TMX), polymethylmethacrylate, andthe like.

Specialty polymeric compositions can be customized and developed forspecific purposes. Specialized and customized materials and compoundedcompositions design and formulations can be commissioned and supplied(Bay Materials Ltd., CA, Landec Corp., CA). Custom synthetic startingmaterials, cross-linking agents, compounding materials, compoundingmixtures, additives, processing techniques, treatments, methods forconditioning, processes, processing equipment, processing techniques andthe like can be used for creating new forms of shape and memory plasticsand putties.

Adjustment of hardening/softening putty characteristics:

The softening/hardening characteristics of color/shape/memory putty canbe adjusted by altering the ratios of thermoplastic to gum base. A fixedconcentration of optical pigment such as a thermochromic pigment,photochromic pigment, photo-luminescent pigment, glitter, or othercolor/optical dye/agent is added at a fixed ratio for a desired opticaleffect.

Dryco ™ Protoplast ™ base Thermoplastic Gum 100%  0% Hardened hightemperature putty  95%  5%  90%  10%  85%  15%  80%  20%  70%  30%  65% 35%  60%  40%  55%  45%  50%  50% Medium temperature putty  45%  55% 40%  60%  35%  65%  30%  70%  25%  75%  20%  80%  15%  85%  10%  90% 5%  95%  0% 100% Low temperature putty

Adjustment of hardening/rubberized putty characteristics:

The softening/rubberized characteristics of color/shape/memory putty canbe adjusted by altering the ratios of thermoplastic to gum base. A fixedconcentration of optical pigment such as a thermochromic pigment,photochromic pigment, photo-luminescent pigment, glitter, or othercolor/optical dye/agent is added at a fixed ratio for a desired opticaleffect.

Evatane ™ Protoplast ™ Polyvinyl Thermo- acetate plastic 100%  0% Highlyrubberized character  95%  5%  90%  10%  85%  15%  80%  20%  70%  30% 65%  35%  60%  40%  55%  45%  50%  50% Medium rubberized character  45% 55%  40%  60%  35%  65%  30%  70%  25%  75%  20%  80%  15%  85% 10% 90%  5%  95%  0% 100% Hardened plastic character

Adjustment of plastic/putty characteristics:

The plastic-like/putty-like characteristics of a color/shape/memorycomposition can be adjusted by altering the ratios of thermoplastic toputty base. A fixed concentration of optical pigment such as athermochromic pigment, photochromic pigment, photo-luminescent pigment,glitter, or other color/optical dye/agent is added at a fixed ratio fora desired optical effect.

Estane Protoplast ™ 5778 ™ Thermo- (TPU) plastic 100%  0% Completemolded shape memory  95%  5% (reversible below transition temp.)  90% 10%  85%  15%  80%  20%  70%  30%  65%  35%  60%  40%  55%  45%  50% 50%  45%  55%  40%  60%  35%  65%  30%  70%  25%  75%  20%  80%  15% 85%  10%  90%  5%  95% Complete loss of mold memory  0% 100%(irreversible at melting transition)

Additional chromic change agents and optical components materials:

Color/shape/memory plastics or putties can be modified to containvarious concentrations of optical change agents. Optical change agentsand stimulating agents can be present in a toothpaste matrix fromgreater than 50% to as low as 0.01%. More usually, the agents will bepresent at 50% to 0.1%. Typically, the agents will be added at between25% and 0.5% and most often between 10% and 1%. The application ofinterest, desired coloration, dye or pigment intensity and opticaldensity, type of optical change agent, and costing considerations helpin determining the concentration to be used.

Alternative thermochromic materials can be utilized including, but notlimited to: light-induced metastable state in a thermochromic copper (H)complexChem. Commun., 2002, (15), 1578-1579 under goes a color changefrom red to purple for a thermochromic complex, [Cu(dieten)2](BF4)2(dieten=N,N-diethylethylenediamine); encapsulated pigmented materialsfrom Omega Engineering Inc.; bis(2-amino-4-oxo-6-methyl-pyrimidinium)tetrachlorocuprate(II); bis(2-amino-4-chloro-6-methylpyrimidinium)hexachlorod-icuprate(II); cobalt chloride; 3,5-dinitro salicylic acid;leuco dyes; spiropyrenes, bis(2-amino-4-oxo-6-methylpyrimidinium)tetrachlorocuprate(II); bis(2-amino-4-chloro-6-methylpyrimidinium)hexachlorod-icuprate(II); cobalt chloride; 3,5-dinitro salicylic acid;leuco dyes; spiropyrenes, bis(2-amino-4-oxo-6-methylpyrimidinium)tetrachlorocuprate(II) and bis(2-amino-4-chloro-6-methylpyrimidinium)hexachlorodicuprate(II), benzo- and naphthopyrans (Chromenes),poly(xylylviologen dibromide, di-beta-naphthospiropyran,Ferrocene-modified bis(spiropyridopyran), isomers of1-isopropylidene-2-[1-(2-methyl-5-phenyl-3-thienyl)ethylidene]-succinicanhydride and the Photoproduct7,7adihydro-4,7,7,7a-tetramethyl-2-phenylbenzo[b]thiophene-5,6-dicarboxylicanhydride, and the like. Encapsulated leuco dyes are of interest sincethey can be easily processed in a variety of formats into a plastic orputty matrix. Liquid crystal materials can be conveniently applied aspaints or inks to surfaces of color/shape/memory composites.

Photochromic dyes can find use in a variety of color change mediums andformats. Photochromic materials can include but are not limited to dyesincluding:1,3-Dihydro-1,3,3-trimethylspiro[2H-indole-2,3-[3]phenanthr[9,10-b](1,4)oxazine];bicyclo [2.2.1]hepta-2,5-diene; benzyl viologen dichloride;4,4′-bipyridyl;6-bromo-1′,3′-dihydro-1′,3′,3′-trimethyl-8-nitrospiro[2H; 5-chloro-1,3-dihydro-1,3,3-trimethylspiro[2H-indole-2,3′-(3H)naphth[2,1-b](1,4)oxazine];6,8-dibromo-1′,3′-dihydro-1′,3′,3′- trimethylspiro[2H;1,1]-diheptyl-4,4′-bipyridinium dibromide;1′,3′-dihydro-5′-methoxy-1′,3′,3′;1′,3′-dihydro-8-methoxy-1′,3′,3′-trimethyl-6-nitrospiro[2H];1′,3′-dihydro-1′,3′,3′-trimethyl-6-nitrospiro[2H-1-benzopyran-2,2′-(2H)-indole];1,3-dihydro -1,3,3-trimethylspiro [2H-Indole-2,3′-[3H]naphth[2,1-b][1,4]oxazine]; 1,1′-dimethyl-4,4′-bipyridinium dichloride;5-chloro-1,3-Dihydro-1,3,3-trimethylspiro[2H-indole-2,3′-(3H)phenanthr[9,10-b](1,4)oxazine];5-methoxy-1,3,3-trimethylspiro[indoline-2,3′-[3H]naphtho[2,1-b]pyran];2,3,3-trimethyl-1-propyl-3H-indolium iodide and the like.

Photo-luminescent compounds can find use in a variety of color changemediums and formats. Photo-luminescent compounds can include, but arenot limited to, a variety, of materials. Greens, green blue and violetcan be made with alkaline earth alurninates activated by rare earthions. By way of example, strontium aluminate can be activated usingeuropium (SrAl03:Eu). Visual wavelengths can include: green at 520 nm,blue-green at 505 nm, and blue at 490 nm. Red and orange colors can begenerated with zinc sulfide.

Fluorescent dyes can find use in various product applications andmediums and formats. Fluorescent dye compounds can include, but are notlimited to: fluorescein, fluorescein, resourcinolphthalein, rhodamine,imidazolium cations, pyridoimidazolium cations, dinitrophenyl,tetramethylrhodamine and the like. A wide range of fluorescent dyes thatcan be activated at various wavelengths and emit light at lowerwavelengths can be purchased from Sigma-Aldrich (Saint Louis, Mo.) orMolecular Probes (Eugene, Oreg.).

Optical change agents can be added in a micro-particulate powder form,in a pellet-compounded form, in slurries, as a compounded form that waspre-mixed and concentrated with the material it is intended to be addedto, added as a colorant in a master batch form, applied to a moldedsurface of shape changing plastic as a solvent based ink, applied to asurface as an ultra-violet ink and cured with ultra-violet light,applied as an adhesive, applied as a durable label fowl, laminated,coated, painted, sprayed, dip coated in an ink or coating composition,or any of a variety of printing, coating, or colorant additive formats.Below illustrates a matrix by way of example but not a limitation as tohow various combinations and permutations can be utilized:

Thermo- Photo- Photo- Shape chromic chromic luminescent Iridescent X X XX X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X XX X X X X X X X X X X X X X

Additives:

Additional additives shown to extend the volume, weight, or expanse aswell as lower the cost of goods of products made of a color/shape/memoryplastic or putty may include, but are not limited to: silicates,diatomaceous earth, sawdust, wood dust, ceramic dust, rubber powder,fiber glass webbing, amorphous materials, glass fibers, fabric, cloth,cheese cloth, netting, screen, cut-out patterned materials, films, sand,pebbles, paper, nylon powder, plastic powder, carbon, talc powder, metalpowder, iron powder, aluminum powder, magnetic particles, paramagneticparticles, plastic micro-particles, micro-capsules, chalk powder, highmelt temperature plastic particles, insoluble inorganic and organicpowders, graphite, insoluble organic compounds, colorant pellets,insoluble inorganic salts, uniform cellulose powder, corn starch,cellulose powders, and the like.

Particulate inert extenders are not intended to change the physicalnature or the shape changing material. The extenders can be transparent,opaque, have independent optical properties such as thermochromic,photochromic, or luminescent characteristics. High temperature plasticssuch as nylon or polyesters can be utilized in a powder form and used asextenders. Extenders can include foaming agents that are capable ofgenerating a high volume of entrapped air.

Alternatively additives can be utilized to change or modify a propertyof a color/shape/memory composition. By way of example, oils,lubricants, surfactants, waxes or the like can be added to a putty toreduce stickiness. Emulsifiers can be added to improve consistency andas an aid for mixing. Fragrances can be added to alter a smell sensationduring use. Gum bases may be added to increase pliability. Encapsulatingelements may be added to provide a carrier means for adding non-misciblematerials.

Shape changing/color changing plastics and putties may be impregnated,laminated, conjoined, permeated, treated onto, dispensed onto, hotmelted into, or otherwise integrated into various fabrics, knittedmaterials, felts, flannel, wire mesh, wire screen, plastic screen,fabric tapes, woven materials and non-woven materials, porous planar andpliable substrates, stretchable nylon, water resistant fabrics, denim,canvas, nylon webbing, or the like. In doing so, the shape/memory/colorchange material may take on some of the added properties of thecompliant substrate. For example, a color/shape/memory plastic can behot laminated onto a knitted nylon fabric. The plastic will be bothstrengthened and become more compliant with the included nylon than ifthe color/shape/memory plastic was comprised without the nylon fabric.Colored, patterned, and lace-like materials can be coated or impregnatedwith a color/shape/memory plastic to take on the color, pattern, orlace-like characteristics of the fabric. Integration with a fabric orpliable substrate can have the added benefit of reducing pricing and yetincreasing intrinsic strength.

Additives can be co-mixed into compositions, coated on compositions,applied as topical treatments or the like depending on the additive andits intended application. For example additives may provide structuralintegrity through reinforcement. Additives may provide protectionagainst environmental effects such as intense light. Ultraviolet lightmay cause premature discoloration. Ultraviolet light inhibiting agentssuch as para-amino-benzoic acid or nano-particulate zinc oxide may beadded to reduce photo-bleaching and promote longer outdoor lifetimes.Chemical resistive agents may be added to improve solvent or chemicalresistance. Additives that protect against high-impact may be added asreinforcing agents. Brighteners may be added to improve a color contrastand improve an appearance. Mold releasing agents can be added to thecomposition to improve release from a forming mold during processing.

Additives will be used at concentrations and percentages that aresuitable to meet the intended requirements. In addition, it will beimportant to add ancillary agents at a level that does not negativelyimpact the intended functionality of a designed optical/shape/memorychange composition. Additives may constitute between 0% to 95% of thetotal mass of a composition. Usually, additives will constitute 0.01% to90% mass. More usually, additives will find use between 0.1% and 75%.Typically, additives will be used between 1% and 50% of the total mass.

Molding processes:

Compression molding can be used with molds that contain high temperatureresistant plastic molds, anodized aluminum molds, non-stick coatedaluminum, polished stainless steel, Kapton™, Teflon™, ceramic, moldreleasing agents coated on molds, molds coated with mold releasingagents. Injection molding can be used where single or multi-cavitymolds, vertical molds, horizontal molds, single composition ormulti-component molds, complex interlocking molds, hot-runner molds,cold runner molds, or the like can be employed. Blow molding, rotarymolding, thermoforming, combination compression-thermoforming, andrelated molding process can be used where convenient. Stamping, rod orfilament drawing, extruding, or other process may be utilized. A widevariety of convention plastic molding process as well as custom moldingprocesses may find use.

Optical light guiding applications:

Optical screens and light sources can be used in connection withoptically transmitting shape changeable plastic shaped pieces. Directoptical coupling can be made between the light source of interest andthe optically transmitting shape changeable plastic. Light sources caninclude incandescent, fluorescent, ultraviolet, light emitting diodes,sun light, electroluminescence, cathode ray tubes, back lit liquidcrystal displays, high definition television screens, common computerterminals, and a variety of other projected light sources.

Shape changing prisms can be utilized whereby the light guided into andout of prisms can be adjusted but a person or child utilizing theoptical shape changing plastic item. Lenses can be created that can bedirectly or indirectly used to vary the focal effects of a lens madewith the optical shape changeable plastic. Fiber optic rods can becreated that guide light and images and can be physically softened orhardened into a configuration of interest in order to maximize an effector optical output. Shape changeable waveguides can be constructed usingoptically clear shape changeable plastics. Waveguides can find use inelectronic and opto-electronic applications.

Holographic imprints can be made in a surface of an optically clearshape changeable plastic. Holograms can be printed on a planar piece, ona contoured piece, or around the circumference of a piece. The hologramcan be made to shift appearance under a wide range of contortions due tothe shape changeable characteristics of the shape changeable plasticsubstrate.

Heating/cooling sources:

Heating sources can include but are not limited to: solar heating,heating by hand, heating by breath, heating with water, heating withmicrowaves, heating with radiant heat, heating with integrated heatingelements, heating with a blow drier, heating with chemically generatedheat, heating with a Peltier plate and the like. Heating processes caninclude light generated heat whereby an optical source can excite a heatgenerating pigment in the plastic composite. As light is absorbed, heatis released from the pigment to locally heat the composition where it isilluminated. Non-optically emitting heat radiating nano-composites mayfind use for generating secondary optical effects in thermochromicpigments.

The following examples are offered by way of illustration and not by wayof limitation.

EXPERIMENTAL Part A.

1. Thermochromic pigment for adding to ink bases or direct addition toshape/memory compositions: A thermochromic pigment composition wasprepared by adding a pre-polymerized polydiacetylenic dimeric amide. Thedimeric amide was made from dimerizing the diacetylenic acid5,7-dodecadiynoic acid with ethylene diamine such that two acid groupscoupled with a single ethylene diamine to make the diamined. The dimericamide was purified and polymerized to a stable pigment using ultravioletlight (254 nanometers). The material was readily powderized using astandard high-speed blade grinder. The powderized form could be readilyadded at various stages of processing of the shape/memory composite.2. Thermochromic ink composition for coating shape/memory materials: Asilk screen printing ink composition was prepared by adding apre-polymerized polydiacetylenic dimeric amide. The dimeric amide wasmade from dimerizing the diacetylenic acid 5,7-dodecadiynoic acid withethylene diamine such that two acid groups coupled with a singleethylene diamine to make the diamined. The dimeric amide was purifiedand polymerized to a stable pigment using ultraviolet light (254nanometers). The pre-polymerized diamide was added at a 10% by weight toa general purpose silk screen ink base (Nazdar Ink Corp.). The mixturewas mixed to homogeneity and stored for use. At room temperature, theformulated ink appeared magenta in color. Upon cooling, the ink shiftedits optical characteristics to a purple/blue color. Upon heating, theink transitioned to a red/orange color. The formulated wet solvent basedink remained stable and exhibited reversible thermochromiccharacteristics at room temperature and only irreversibly turned colorif heated above 150 F. The ink base when dried retained its reversiblethermochromic color change ability up to 250 F.3. Shape/memory/color changing sheet: A 30° C. shape/memory plasticsheet (0.015 in thickness) was purchased from Bay Materials, Corp.(Menlo Park, Calif.). The sheet was cut to a 6 inch by 9 inch rectangleand kept flattened until use. The sheet was screen printed using thethermochromic general purpose ink composition prepared as Example 2above. An opaque coating was generated by using multiple screen coatingpasses using a 240 mesh silk screen with a 8 inch by 10 inch windowsize. Coating was done on only one side of the sheet. The coating wasallowed to dry overnight prior to further use.The dried coated shape/memory/color changing sheet exhibited strongthermochromic color change and temperature reversibility by cyclingtemperature above and below 30° C. The sheet was fully pliable andcompliant when warmed. Likewise, the sheet turned from a roomtemperature magenta color to a red/orange color when warmed above 30° C.The sheet began to stiffen and solidify as well as change color to adeep magenta when cooled to 25° C. The sheet retained any shape it washeld in during the cooling process. At 20° C. the sheet became stiff andhardened to a rigid plastic-like character as well as adopting darkerpurple color.Both the shape and color change were completely reversible above andbelow the temperature set points. The shape could be set and resetnumerous times. The associated color change served as an excellentindicator that softening was instantly going to occur as well as aninteractive and attractive optical effect which added play value to thecomposition.4. Shape/memory/color changing fiber: A 30° C. shape/memory plasticfiber was prepared to a diameter of 0.02 inch in diameter. Elongatedfilaments of a polymeric lactide composition were drawn from a melt. Thefilaments were pulled at a steady rate and tension such that continuouslengths of filaments (0.02 inch in dia.). The material stiffenedimmediately after being pulled form the melt. The filaments were spunonto a real for storage. The filaments were coated with the reversiblethermochormic ink prepared as described in example 2. After coating anddrying, both the shape and color of the coated fiber could be changed byexposure to temperatures above room temperature.5. Shape/memory/color changing doll hair: 30° C. shape/memory plasticfiber (0.015 in dia.) was purchased from Bay Materials, Corp. (MenloPark, Calif.). The fiber was cut into 10 inch segments and fixedside-by-side on a 8 inch by 10 inch wooden frame using double stickfoam-based tape. The strands were space approximately 3 millimetersapart and kept with tension. The strands were coated with a thin opaquecoating using the ink base prepared as in Example 2. Coating wasaccomplished by brush on both sides of the fibers by coating on one sideand then flipping the frame to coat on the other side. After drying for6 hours at room temperature, the strands were removed by cuttingimmediately along the attachment points. The final coated fiber strandswere 7.5 inches in length.A bundle of approximately 400 strands were grouped and attached togetherat one end by melting the adjacent strands using a heated Teflon coatedsurface (350° F.). The strand group had the appearance of toy doll hair.The hair could be shape and color changed by exposure to temperaturesabove 90° F. The stiff strands would immediately soften and change froma room temperature magenta color to a red/orange color. Continuedsoftening and color brightening to an orange yellow color occurred whenthe exposed temperature was raised to above 100° F.The hair bundle could be readily molded into any shape or braidedpattern when warmed and manipulated. The shape or braided pattern couldbe frozen in shape by lowering the ambient temperature to 70 F or lower.Shape freezing could be accomplished by passing cool air over the bundleor by submersing the bundle in cooled water. Both the shape and colorsimultaneously changed upon warming and cooling. The shape and colorchange were completely reversible over repeated cycles.6. Woven shape, memory, and color changing fabric: Shape/memory/colorchanging fabric was prepared using shape/memory/color changing fibersprepared as described in Example 5 above. A fabric was prepared using asimple loom. A 6 inch by 6 inch fabric sheet was prepare and stitchsealed along each of the 4 edges. The shape/memory/color change fabricsheet was further secured by heat sealing the oven strands along the 4edges of the fabric sheet.The fabric sheet could be readily molded into any shape or configurationwhen warmed and manipulated. The shape or configuration could be frozenin shape by lowering the ambient temperature to 70 F or lower. Shapefreezing could be accomplished by passing cool air over the fabric sheetor by submersing the sheet in cooled water. Both the shape and colorsimultaneously changed upon warming and cooling. The shape and colorchange were completely reversible over repeated cycles.7. Shape/memory/color changing Epoxy resin: Shape/memory/color changingepoxy resin was prepared by adding the thermochromic pigment describedin Example 1 at a ration of 5% pigment by weight of 95% weight Epoxy(Devcon 5 Minute Epoxy, All Purpose, ITW Performance Polymers ConsumerDivision). The thermochromic pigment was added directly to the fastdrying Epoxy component in a highly powderized form. The pigment wasthoroughly mixed. The mixture could be stored indefinitely at roomtemperature prior to mixing with the resin's hardener component. Foruse, the two components of the Epoxy resin were added in equal amountsand mixed thoroughly.When the two components were mixed, the thermochromic pigment served asan indicator of uniformity of mixing during the mixing process. As thetwo components were mixed, the thermochromic pigment changed color froma magenta color to a red transition as the exothermic polymerizationreaction occurred within the Epoxy resin. The color continued toprogress to a bright orange color during the prescribed 5 minute timeframe specified by the Epoxy resin manufacturer. A bright yellow orangecolor occurred in the mixture immediately prior to the resinsolidifying. After solidification and cooling, the composite colorreturned to a magenta color at room temperature (72 F) and reversibly toa blue/purple color below 60 F.Adjusting the ratios of Epoxy to hardener could be used to adjust thefinal stiffness of the polymerized resin. Ratios of hardener to Epoxygreater than 50% hardener resulted in stiffer composites with fast shapememory characteristics. Ratios of hardener to Epoxy less than 50%hardener resulted in less rigid composites with slower shape memorycharacteristics.The multi-element shape/memory/color change Epoxy resin could be moldedinto a wide variety of initial shapes, configurations, geometries, sheetforms, rod forms, strand forms, patterns and the like. Each shape couldbe pre-designed for an initial shape which could be reformed uponheating, holding the shape and subsequent cooling. Upon re-heating, theEpoxy resin would return to its original shape.8. Doll possessing shape/memory/color changing hair and body: A playdoll possessing both body and hair shape/memory/color changecharacteristics was prepared. A mold was prepared using a commerciallyavailable room temperature vulcanization molding material. The mold wasmade from a small plastic figure doll 3 inch in height and 0.5 inch inwidth. The doll was molded using the thermochromic shape/memory/colorchange Epoxy resin described in Example 7, above. The Epoxy resin wasused at a ratio of 50% hardener to 50% Epoxy. The molded doll, oncehardened was modified with a 0.25 inch in diameter hole at the top ofthe doll's head.The doll was attached with a 7.5 inch segment of bundledshape/memory/color change hair described in Example 5. The bluntconnected end of the hair bundle was glued in place by attaching thebundle end inside of the drilled hole in the doll head.The hair bundle and doll could be readily molded into any shape orbraided pattern when warmed and manipulated. The shape or braidedpattern could be frozen in shape by lowering the ambient temperature to70 F or lower. Shape freezing could be accomplished by passing cool airover the hair bundle and doll or by submersing it into cooled water.Both the shape and color simultaneously changed upon warming andcooling. The shape and color change were completely reversible overrepeated cycles.9. Shape/memory/color shifting tooth brush handle: A toothbrush handlecomprising of a shape changing material, a relief material to enhanceshape memory and a thermochromic material indicating the temperaturetransition was prepared in a molded form. A 30 C shape memory materialwas purchased from Bay Materials, LLC. (Menlo Park, Calif.). Thethermochromic pigment was prepared according to Example 1. A reliefmaterial with good spring back characteristics was prepared with 0.30inch thick polyester sheet stock.A toothbrush head was removed from a standard retail tooth brush. Thecut end was slotted to facilitate attachment to the shape/memory/colorshifting handle. An aluminum mold was prepared using standard machiningtechniques. The mold was equipped with ejector pins to remove the moldpiece after molding. The mold was constructed to adapt the toothbrushhead in a position that would lock the toothbrush head with the moldedhandle. The mold also included a design to accept a die cut pattern ofthe relief material shaped the same as the final toothbrush handle. Therelief material was die cut with a 30% smaller profile than the moldsuch that the molded shape changing material would completely encase therelief material. The die cut relief material was accurately placed inthe mold along with the toothbrush head.Prior to molding, the polydiacetylcnic pigment described in Example 1blended with a granulated form of the 30 C shape changing material. Thepigment was added at a concentration of 2% by weight of the shapechanging material. The shape memory material mixed with thermochromicpigment was pre-heated and blended at 280 F. The blended material wasworked into the mold and the material pressed under pressure to flowthroughout the mold cavity. Pressures of 2000 pounds/square inch wereapplied during the heating/molding process. The mold and composite werecooled to room temperature prior to removal. The finishedshape/memory/color shifting toothbrush was ejected from the mold usingthe ejector pins. The final product looked like a standard toothbrushpossessing a magenta color at room temperature.The brush maintained it shape and color at room temperature (+/−2 F).The shape could be frozen in shape by lowering the ambient temperatureto 70 F or lower. Shape freezing could be accomplished by passing coolair over the brush or by submersing it in running tap water. Both theshape and color simultaneously changed upon warming the brush handleunder warm running tap water. The shape and color change were completelyreversible over repeated cycles.The shape/memory/color change handle had the additional advantage ofbeing bent and shaped such that the handle could be self-standing. Bywarming and twisting the handle end, a small circular patternperpendicular to the length of the brush could be created and frozen inshape. The shape changed end provide a stand which permitted the brushto stand upright on its own and thus not requiring a holder for thebrush.10. Adhesives containing reversible thermochromic C14EDAC14 wereprepared using a commercially available adhesive resin (39% C0472 fromLandec). Polymerized magenta C14EDAC14 was mixed at concentrationsranging from 0.01% to 50% by weight. The resin was spread onto papersand solid supports and dried to form a pressure sensitive adhesive withdistinct thermochromic color transition properties resulting from thepolymeric C14EDAC14. Adhesives resins were dried either at room temp. orup to 220° F. The thermochromic adhesive was magenta at room temp, bluebelow room temp., and transitioned to red at about 90-100° F. The colorchange further advanced to an orange color at a 120° F. and subsequentlyto a yellow color at 200° F. The dried adhesive thermochromiccomposition exhibited reversible properties up to 250-290° F. Theadhesive can be mixed with a variety of other compositions to providefor unique pressure sensitive adhesive applications.11. Plastic toy horse possessing shape/memory/color changing hair andmane:12. Electra-conductive shape/color change fibers for hair and wovenmaterials:13. Thermoelectric patterning for inducing color and shape from 2Dobject to 3D object:14. Embedded translucent holographic image in transparent shape/memorymaterial15. Die cut shape/memory/color changing bath toy:16. Heat shrink shape/color change film with thermoelectric heatingelement for induction:17. Electo-heat responsive shape/color changing toy configuration:18. Electro-heat responsive printed color/shape changing patterns onheat shrink film:19. Color changing bi-directional heat shrink plastics (e.g. ShrinkyDink™ patterns:20. Printed edible sugar laminate layered on pre-molded shape changingplastic:21. Electro-thermal hair brush for inducing color/shape change incolor/shape/memory change hair:22. Shape/memory/color changing food dish formed from thermally annealedsheet:23. Area on thermoformed packaging which changes shape and color whenput on hot water cup:24. Optical grade self-adjustable lenses for eye glasses and visualeffects:25. Edible sugar layer which changes shape and graphics upon heating:26. Conductive removable wound or tissue dressing:27. Heat shrink for building materials and facilitating closures:28. Color/shape changing/melting Crayons™:29. Cold storage, collapsible storage containers, collapsible consumerproducts:30. Epoxy-based resins found use as a shape/memory component for theplural composition:31. Color/shape/memory changing pop-up books:

Part B. EXAMPLE 1

Thermochromic color/shape/memory plastic composition: A thermochromiccolor and shape changing plastic composition with combined shape memoryproperties was formulated using a the thermoplastic polyurethane Estane™5778 (Noveon Corporation, Cleveland Ohio) and 2.5% by weight powderedthermochromic pigment (Keystone Aniline Corporation, Chicago Ill.).

Small batches were prepared using 250 grams thermoplastic and 6.25 gramsthermochromic pigment. A rounded bottom Pyrex™ dish (1000 ml. volume)was used for mixing. The bowl could be coated with a lubricating oil toreduce adhesion on the bowl sides. For compression molding applications,the thermoplastic was melted in a microwave oven for 2-4 minutes andmixed to a viscous flowing consistency. The thermochromic powder wasadded while mixing to a uniform opacity. Complete mixing wasaccomplished over several minutes. Repeated heating by microwave for 30to 60 seconds was done to ensure a molten consistency.

Large batches were prepared using identical ratios of thermoplastic tothermochromic colorant as described above. 25 kilogram batches wereprepared in a heated industrial mixing vat. The vat was equipped with auniform heating jacket and an industrial grade mixing implement.Pre-dried pellet stock of the thermoplastic were added to the pre-heatedvat. A temperature between 350° F. and 400° F. was maintained. Mixingwas initiated after a uniform molten state was achieved. Mixing wasmaintained at a slow but steady state. 625 grams thermochromic colorantwas added slowly to the mixing batch and mixing was maintained for 10 to30 minutes. The viscous molten mixture was periodically conditioned byadditional physical displacement using a large spatula.

The finalized molten mixtures could be used directly in the molten stateby transfer in-line to accompanying production molding dies andequipment or the mixture could be separated into usable portions andsolidified and pre-shaped into convenient ingots for storage, inventory,and later use.

EXAMPLE 2

Photochromic color/shape/memory plastic composition: A photochromiccolor and shape changing plastic composition with combined shape memoryproperties was formulated using the thermoplastic polyurethane Estane™5778 (Noveon Corporation, Cleveland, Ohio) and 2.5% by weight powderedphotochromic pigment (Color Change Corporation, Streamwood, Ill.).

Small batches were prepared using 250 grams thermoplastic and 6.25 gramsphotochromic pigment. A rounded bottom Pyrex™ dish (1000 ml. volume) wasused for mixing. The bowl could be coated with a lubricating oil toreduce adhesion on the bowl sides. For compression molding applications,the thermoplastic was melting in a microwave oven for 2-4 minutes andmixed to a viscous flowing consistency. The photochromic powder wasadded while mixing to a uniform opacity. Complete mixing wasaccomplished over several minutes. Repeated heating by microwave for 30to 60 seconds was done to ensure a molten consistency.

Large batches were prepared using identical ratios of thermoplastic tophotochromic colorant as described above. 25 kilogram batches wereprepared in a heated industrial mixing vat. The vat was equipped with auniform heating jacket and an industrial grade mixing implement.Pre-dried pellet stock of the thermoplastic were added to the pre-heatedvat. A temperature between 350° F. and 400° F. was maintained. Mixingwas initiated after a uniform molten state was achieved. Mixing wasmaintained at a slow but steady state. 625 grams photochromic colorantwas added slowly to the mixing batch and mixing was maintained for 10 to30 minutes. The viscous molten mixture was periodically conditioned byadditional physical displacement using a large spatula.

The finalized molten mixtures could be used directly in the molten stateby transfer in-line to accompanying production molding dies andequipment or the mixture could be separated into usable portions andsolidified and pre-shaped into convenient ingots for storage, inventory,and later use.

EXAMPLE 3

Multi-format photochromic/thermochromic color/shape/memory plasticcomposition: A photochromic/thermochromic color and shape changingplastic composition with combined shape memory properties was formulatedusing a the thermoplastic polyurethane Estane™ 5778 (Noveon Corporation,Cleveland Ohio), 2.5% by weight powdered photochromic pigment (31° C.magenta Color Change Corporation, Streamwood Ill.), and 2.5% by weightpowdered thermochromic pigment (Keystone Aniline Corporation, ChicagoIll.).

Small batches were prepared using 250 grams thermoplastic, 6.25 gramsphotochromic pigment and 6.25 grams thermochromic pigment. A roundedbottom Pyrex™ dish (1000 ml. volume) was used for mixing. The bowl couldbe coated with a lubricating oil to reduce adhesion on the bowl sides.For compression molding applications, the thermoplastic was melted in amicrowave oven for 2-4 minutes and mixed to a viscous flowingconsistency. The photochromic and thermochromic powders were added whilemixing to a uniform opacity. Complete mixing was accomplished overseveral minutes. Repeated heating by microwave for 30 to 60 seconds wasdone to ensure a molten consistency.

Large batches were prepared using identical ratios of thermoplastic tophotochromic and thermochromic colorants as described above. 25 kilogrambatches were prepared in a heated industrial mixing vat. The vat wasequipped with a uniform heating jacket and an industrial grade mixingimplement. Pre-dried pellet stock of the thermoplastic were added to thepre-heated vat. A temperature between 350° F. and 400° F. wasmaintained. Mixing was initiated after a uniform molten state wasachieved. Mixing was maintained at a slow but steady state. 625 gramsphotochromic and 625 grams thermochromic colorants were added slowly tothe mixing batch and mixing was maintained for 10 to 30 minutes. Theviscous molten mixture was periodically conditioned by additionalphysical displacement using a large spatula.

The finalized molten mixtures could be used directly in the molten stateby transfer in-line to accompanying production molding dies andequipment or the mixture could be separated into usable portions andsolidified and pre-shaped into convenient ingots for storage, inventory,and later use. The final composition comprised and exhibited all of theexpected shape change, thermochromic and photochromic characteristicsexpected.

EXAMPLE 4

Photo-luminescent (glow-in-the-dark) color/shape/memory plasticcomposition: A photo-luminescent color and shape changing plasticcomposition with combined shape memory properties was formulated using athe thermoplastic polyurethane Estane™ 5778 (Noveon Corporation,Cleveland Ohio) and 15% by weight powdered photo-luminescent pigment(Glow Incorporated, Severn Md.).

Small batches were prepared using 250 grams thermoplastic and 37.5 gramsphoto-luminescent pigment. A rounded bottom Pyrex™ dish (1000 ml.volume) was used for mixing. The bowl could be coated with a lubricatingoil to reduce adhesion on the bowl sides. For compression moldingapplications, the thermoplastic was melted in a microwave oven for 2-4minutes and mixed to a viscous flowing consistency. Thephoto-luminescent powder was added while mixing to a uniform opacity.Complete mixing was accomplished over several minutes. Repeated heatingby microwave for 30 to 60 seconds was done to ensure a moltenconsistency.

Large batches were prepared using identical ratios of thermoplastic tophoto-luminescent colorant as described above. 25 kilogram batches wereprepared in a heated industrial mixing vat. The vat was equipped with auniform heating jacket and an industrial grade mixing implement.Pre-dried pellet stock of the thermoplastic were added to the pre-heatedvat. A temperature between 350° F. and 400° F. was maintained. Mixingwas initiated after a uniform molten state was achieved. Mixing wasmaintained at a slow but steady state. 3.75 kilograms photo-luminescentcolorant was added slowly to the mixing batch and mixing was maintainedfor 10 to 30 minutes. The viscous molten mixture was periodicallyconditioned by additional physical displacement using a large spatula.

The finalized molten mixtures could be used directly in the molten stateby transfer in-line to accompanying production molding dies andequipment or the mixture could be separated into usable portions andsolidified and pre-shaped into convenient ingots for storage, inventory,and later use.

EXAMPLE 5

Multi-format photochromic/photo-luminescent optical/shape/memory plasticcomposition: A photochromic and photo-luminescent optical and shapechanging plastic composition with combined shape memory properties wasformulated using a the thermoplastic polyurethane Estane™ 5778 (NoveonCorporation, Cleveland Ohio), 2.5% by weight powdered photochromicpigment (31° C. magenta Color Change Corporation, Streamwood Ill.), and10% by weight powdered photo-luminescent pigment (Glow Incorporated,Severn Md.).

Small batches were prepared using 250 grams thermoplastic, 6.25 gramsphotochromic pigment and 37.5 grams photo-luminescent pigment. A roundedbottom Pyrex™ dish (1000 ml. volume) was used for mixing. The bowl couldbe coated with a lubricating oil to reduce adhesion on the bowl sides.For compression molding applications, the thermoplastic was melted in amicrowave oven for 2-4 minutes and mixed to a viscous flowingconsistency. The photochromic and photo-luminescent powders were addedwhile mixing to a uniform opacity. Complete mixing was accomplished overseveral minutes. Repeated heating by microwave for 30 to 60 seconds wasdone to ensure a molten consistency.

Large batches were prepared using identical ratios of thermoplastic tophotochromic and thermochromic colorants as described above. 25 kilogrambatches were prepared in a heated industrial mixing vat. The vat wasequipped with a uniform heating jacket and an industrial grade mixingimplement. Pre-dried pellet stock of the thermoplastic were added to thepre-heated vat. A temperature between 350° F. and 400° F. wasmaintained. Mixing was initiated after a uniform molten state wasachieved. Mixing was maintained at a slow but steady state. 625 gramsphotochromic and 3.75 kilogram photo-luminescent colorants were addedslowly to the mixing batch and mixing was maintained for 10 to 30minutes. The viscous molten mixture was periodically conditioned byadditional physical displacement using a large spatula.

The finalized molten mixtures could be used directly in the molten stateby transfer in-line to accompanying production molding dies andequipment or the mixture could be separated into usable portions andsolidified and pre-shaped into convenient ingots for storage, inventory,and later use. The final composition comprised and exhibited all of theexpected shape change, photochromic, and photo-luminescentcharacteristics expected. In day light, a region illuminated withultraviolet light (e.g. a 400 nanometer light emitting diode pen light)becomes colored from a non-colored plastic background to a deeplycolored pattern in the illuminated areas. While the photochromic effectdissipates within 1-2 minutes, the same illuminated area would emit anoptical glow in dark conditions.

EXAMPLE 6

Low temperature thermochromic color/shape/hardening putty composition: Athermochromic color and shape-changing putty composition with combinedreversible shape hardening properties was formulated using a the gumbase Dreyco™ base (L.A. Dreyfus Company, Edison N.J.), the thermoplasticcomposition Protoplast™ (WRF/Aquaplast Corporation, Wyckoff N.J.) and 4%by weight powdered thermochromic pigment (Keystone Aniline Corporation,Chicago Ill.).

Batches were prepared using a ratio of 2.5 parts Dreyco™ base: 1 partProtoplast™ thermoplastic: 1% by total weight powdered thermochromicpigment. Pellets of the Dreyco™ base were rinsed in warm water andallowed to soften in water at 120° F. for 10 minutes. The bulk wasaggregated and mixed into a uniform dough-like consistency. The bulk ofDreyco™ base was kept warm while Protoplast™ thermoplastic pellets wereheated by microwave until a viscous consistency that matched that of thewarmed Dreyco™ base. The powdered thermochromic pigment was addeddirectly to the molten thermoplastic and mixed until it was uniformlydispersed. The Dreyco™ base and mixed thermoplastic and thermochromicpigment were combined and uniformly mixed. The mixture was periodicallywarmed either by microwave or with 120° F. water to ensure a softenedstate during mixing.

The finalized softened mixture could be used directly in the softenedstate by transfer in-line to accompanying production molding dies andequipment or the mixture could be separated into usable portions andsolidified and pre-shaped into convenient ingots for storage, inventory,and later use.

EXAMPLE 7

Low temperature photochromic color/shape/hardening putty composition: Aphotochromic color and shape changing putty composition with combinedreversible shape hardening properties was formulated using a the gumbase Dreyco™ base (L.A. Dreyfus Company, Edison N.J.), the thermoplasticcomposition Protoplast™ (WRF/Aquaplast Corporation, Wyckoff N.J.) and 4%by weight powdered photochromic pigment (Color Change Corporation,Streamwood Ill.).

Batches were prepared using a ratio of 2.5 parts Dreyco™ base: 1 partProtoplast™ thermoplastic: 1% by total weigh weight powderedphotochromic pigment. Pellets of the Dreyco™ base were rinsed in warmwater and allowed to soften in water at 120° F. for 10 minutes. The bulkwas aggregated and mixed into a uniform dough-like consistency. The bulkof Dreyco™ base was kept warm while Protoplast™ thermoplastic pelletswere heated by microwave until a viscous consistency that matched thatof the warmed Dreyco™ base. The powdered photochromic pigment was addeddirectly to the molten thermoplastic and mixed until it was uniformlydispersed. The Dreyco™ base and mixed thermoplastic and photochromicpigment were combined and uniformly mixed. The mixture was periodicallywarmed either by microwave or with 120° F. water to ensure a softenedstate during mixing.

The finalized softened mixture could be used directly in the softenedstate by transfer in-line to accompanying production molding dies andequipment or the mixture could be separated into usable portions andsolidified and pre-shaped into convenient ingots for storage, inventory,and later use.

EXAMPLE 8

Low temperature photo-luminescent color/shape/hardening puttycomposition: A photo-luminescent color and shape changing puttycomposition with combined reversible shape hardening properties wasformulated using a the gum base Dreyco™ base (L.A. Dreyfus Company,Edison N.J.), the thermoplastic composition Protoplast™ (WRF/AquaplastCorporation, Wyckoff N.J.) and 15% by weight powdered photo-luminescentpigment (Glow Incorporated, Severn Md.).

Batches were prepared as above in examples “Low temperature photochromiccolor/shape/hardening putty composition”. The finalized softened mixturecould be used directly in the softened state by transfer in-line toaccompanying production molding dies and equipment or the mixture couldbe separated into usable portions and solidified and pre-shaped intoconvenient ingots for storage, inventory, and later use.

EXAMPLE 9

High temperature thermochromic, photochromic or photo-luminescentcolor/shape/hardening putty compositions: A thermochromic, photochromic,or photo-luminescent color and shape changing putty composition withcombined reversible shape hardening properties was formulated using thethermoplastic composition Protoplast™ (WRF/Aquaplast Corporation,Wyckoff N.J.) and 4% by weight powdered thermochromic pigment (KeystoneAniline Corporation, Chicago Ill.); 4% by weight powdered photochromicpigment (Color Change Corporation, Streamwood Ill.); or 15% by weightpowdered photo-luminescent pigment (Glow Incorporated, Severn Md.).

Batches were prepared as above in examples “Low temperaturethermochromic color/shape/hardening putty composition”. The finalizedsoftened mixture could be used directly in the softened state bytransfer in-line to accompanying production molding dies and equipmentor the mixture could be separated into usable portions and solidifiedand pre-shaped into convenient ingots for storage, inventory, and lateruse.

EXAMPLE 10

Pressure molded optical effect thermochromic, photochromic,photo-luminescent color/shape/memory changing plastic sheets and surfacepatterned items: Optical effect color/shape/memory plastic batches weremade in accordance with examples above “Thermochromic color/shape/memoryplastic composition”; “Photochromic color/shape/memory plasticcomposition”; or “Photo-luminescent (glow-in-the-dark)color/shape/memory plastic composition”.

Pre-sized amounts of individual optical/shape/memory plastic formulatedmixtures were brought to a soft semi-molten state. A molten pre-sizedamount was placed on a non-stick mold surface. The mold surface waseither patterned with a surface relief pattern that was to be imprintedon into the final product or the surface was a flat surface for plainsheet preparation. The mold was pre-warmed to 300° F. using an internalelectrical heating element. A second pre-heated mold surface wasoriented directly above the bottom plate surface and positioned with a30 ton pneumatic actuated press.

The semi-molten plastic was compressed using the actuated pneumaticpress. The mold and press were designed to make complete contact betweenthe upper mold surface and lower mold surface. Excess molten plastic wasallowed to escape through guided troughs. Compression was accomplishedusing a 30 seconds molding cycle. After compression, the top and bottommold plates and compressed plastic were removed from the press andallowed to rapidly cool with either running water or a stream of coldair. The mold plates were separated and the molded plastic item removedand trimmed.

EXAMPLE 11

Direct pressure molded optical effect thermochromic, photochromic,photo-luminescent color/shape/memory changing plastic structures:Optical effect color/shape/memory plastic batches were made inaccordance with examples above “Thermochromic color/shape/memory plasticcomposition”; “Photochromic color/shape/memory plastic composition”; or“Photo-luminescent (glow-in-the-dark) color/shape/memory plasticcomposition”.

Pre-sized amounts of individual optical/shape/memory plastic formulatedmixtures were brought to a soft semi-molten state. A molten pre-sizedamount was placed on a non-stick mold surface as in the example“Pressure molded optical effect thermochromic, photochromic,photo-luminescent color/shape/memory changing plastic sheets and surfacepatterned items”. Three-dimensional mold plates were machined such thatthe mold plate exactly mirrored the bottom plate. Mold cavities werecreated to provide a 25/1000 inch spacing between the top plate and thebottom plate throughout each impression structure. Escape channels werecreated within the mold surface to provide for channeling excess moltenplastic. The mold was pre-warmed to 300° F. using an internal electricalheating element. Mold plates were positioned with a 30 ton pneumaticactuated press.

The semi-molten plastic was compressed using the actuated pneumaticpress. The mold and press were designed to make complete contact betweenthe upper mold surface and lower mold surface. Excess molten plastic wasallowed to escape through the guided escape channels. Compression wasaccomplished using a 30 to 60 seconds molding cycle. After compression,the top and bottom mold plates and compressed plastic were removed fromthe press and allowed to rapidly cool with either running water or astream of cold air. The mold plates were separated and the moldedplastic item removed and trimmed.

Doll figures, faces, characters, dimensional shapes, action figures,cartoon figures and shapes and the like were machined for molding.Multiple repeats of molded features were machined into the mold toensure the maximum number of molded features were produced per cycle.Care was taken to ensure adequate filling of the mold cavities.Initially, the top and bottom mold pieces was brought in contact withthe molten plastic and slowly compressed at specified rates duringcompression to ensure cavity filling.

Final thermoformed pieces retained their thermochromically active,photochromically active, or photo-luminescently active properties. Afterthermoforming, the molded items were cut out either by hand or using adie cutting process. Final items exhibited complete intended pluralshape and optical properties for the representative sheet materialsutilized.

EXAMPLE 12

Thermoformed thermochromic color/shape/memory changing plastic bathtoys, figures, and play pieces using planar sheets: Optical effectcolor/shape/memory plastic sheets were prepared from batches made inaccordance with examples above “Thermochromic color/shape/memory plasticcomposition”; “Photochromic color/shape/memory plastic composition”; or“Photo-luminescent (glow-in-the-dark) color/shape/memory plasticcomposition” and in accordance with the example “Pressure molded opticaleffect thermochromic, photochromic, photo-luminescent color/shape/memorychanging plastic sheets and items” above.

Planar pressure formed sheets (20/1000 inch thick) were shaped usingstandard thermoforming processes. Thermoforming molds were machinedusing aluminum mold making stock. Doll figures, faces, characters,dimensional shapes, action figures, cartoon figures and shapes and thelike were machined for molding. Multiple repeats of molded features weremachined into the mold to ensure the maximum number of molded featureswere produced per cycle. 12 inch by 12 inch sheets were thermoformedusing 4 repeat unit molds to yield 4 items per cycle. The sheets wereconditioned at 250° F. and rapidly thermoformed to ensure sagging.

Final thermoformed pieces retained their thermochromically active,photochromically active, or photo-luminescently active properties. Afterthermoforming, the molded items were cut out either by hand or using adie cutting process. Final items exhibited complete intended pluralshape and optical properties for the representative sheet materialsutilized.

EXAMPLE 13

Optical glow rods possessing plural shape changeable properties, opticalclarity and light diffusion properties: Planar sheets, 2 to 8 mm thickin increments of 1 mm, with shape memory properties were formulatedusing a the thermoplastic polyurethane Estane™ 5778 (Noveon Corporation,Cleveland OH) 0.01%-0.05% by weight finely particulate mica (shimmerpowder) was either added or not to enhance light diffusion. Molding wasaccomplished using a planar mold configuration described in the exampleabove: “Pressure molded optical effect thermochromic, photochromic,photo-luminescent color/shape/memory changing plastic sheets and surfacepatterned items”.

Sheets were prepared with smooth top and bottom surfaces. Finishedsheets were die cut or cut with a hot knife to yield strips with a widthequal to the thickness of a particular sheet. Cut pieces were finishedto have smooth polished edges similar to the smooth finish on the topand bottoms. Strips were sectioned into 6, 8 , 10, or 12 inch lengths.Illumination of the end, side, or top of a strip with a variety ofintense and focused light sources resulted in an evanescent glowthroughout the strip. Strips containing a low percentage of opticaleffect pigment gave a more uniform and intense glow than those stripswithout pigment.

Other shapes were formed using molding features and or extrusion.Cross-sectional circular, angular, triangular, pentagon shaped,hexagonal shaped or other geometrical cross-sectional designs weremolded. In each case, directional rods retained their shape change andoptical effect. Light directed at essentially any angle could be used tocause a glow-like characteristic to the rod types.

EXAMPLE 14

Illumination surface for light transmission into and through shapechangeable optical plastic items: An illumination system comprised withoptical glow rods prepared in example “Optical glow rods possessingplural shape changeable properties, optical clarity and light diffusionproperties” above. An illumination pad with a back light and opaquesurface cover was developed. The opaque surface was designed with arefractive index that blocks light in the dry state. When hydrated withwater or an index matching medium, light could escape from the back litpanel. Light could only escape on areas of the opaque surface cover thathave been contacted by an indexing medium (water).

Illumination can be enhanced and directed using wetted optical glow rodsplaced on the opaque surface cover. The wetted rod side directlyconducts light through the opaque layer and into the rod causing the rodto appear to glow. Shape changeable glow rods can be shaped and modeledto create various patterns, figures, messages, and designs. A shapechangeable glow rod can initially be molded to desired planarconfiguration. When the rod is wetted along its side and placed on theopaque darkened surface, light will be transmitted through the layer dueto index matching of water and the rod will be selectively illuminatedin the pre-determined shape that the rod had been molded to.

Shape changeable glow rods provide a three-dimensional relief appearanceon the illumination pad. The optical effect can be modulated byrepositioning or remolding a shape changeable light transmitting glowrod. Glow rods can be utilized with different optical componentsincluding fluorescent dyes, glitters, dyes with optical clarity forchanging the rods color, glow-in-the-dark pigments, iridescent pigmentsand the like.

EXAMPLE 15

Drawn optical effect thermochromic, photochromic, photo-luminescentcolor/shape/memory changing plastic strands, filaments, and doll hair:Optical effect color/shape/memory plastic batches were made inaccordance with examples above “Thermochromic color/shape/memory plasticcomposition”; “Photochromic color/shape/memory plastic composition”; or“Photo-luminescent (glow-in-the-dark) color/shape/memory plasticcomposition”.

Pre-sized amounts of individual optical/shape/memory plastic formulatedmixtures were brought to a soft semi-molten state in a temperaturecontrolled heating jacket. The temperature was adjusted to ensureuniform viscosity and mixing. Molten mixtures were maintained between300° F. and 350° F. Fibers were drawn from the molten mixture byinitially contacting the mixture surface, pulling a filament to aspindle and maintaining a constant rotational rate for the spindle todraw the filament. The spindle was kept at a fixed distance from moltenplastic surface (3 feet). The distance provided adequate time for theplastic to harden for bundling on the spindle. Typically pullingvelocities were maintained at between 10 to 100 feet per minute. Pullingvelocities, molten temperatures, cooling distances and relatedparameters could be adjusted accordingly to produce thin or thickenedstrands, filaments, or hair product.

Final drawn filament compositions retained their thermochromicallyactive, photochromically active, or photo-luminescently activeproperties. After formation, the filaments items were bundled and cutfrom doll hair, re-wound for rooting into plastic doll heads or storedfor various toy applications. Finished filaments and hair itemsexhibited complete intended plural shape and optical properties for therepresentative sheet materials utilized.

Physical properties of the optical effect thermochromic, photochromic,photo-luminescent strands, filaments, and doll hair compositions couldbe modified for particular applications, By way of example, otherplastic that provide increased pull strength could be added to provideadditional stability during the doll hair rooting process. Lubricantscould be added to reduce sticking between strands. Other physicalproperties pertaining to processing, manufacturing and functionalitycould be adjusted accordingly depending on the application of interest.

EXAMPLE 16

Sand/plastic compositions comprising optical effect thermochromic,photochromic, or photo-luminescent color/shape/memory changingproperties: Optical effect color/shape/memory plastic batches were madein accordance with examples above “Thermochromic color/shape/memoryplastic composition”; “Photochromic color/shape/memory plasticcomposition”; or “Photo-luminescent (glow-in-the-dark)color/shape/memory plastic composition”.

Pre-sized amounts of individual optical/shape/memory plastic formulatedmixtures were brought to a soft semi-molten state in a temperaturecontrolled heating jacket. Washed clean fine grain sand was added frombetween 1% by volume to 50% by total volume. The sand was added inslowly and mixed thoroughly to ensure complete coverage of all sandparticulate with the thermoplastic composition.

Final compositions retained their thermochromically active,photochromically active, or photo-luminescently active properties. Theadded sand provided a grainy finish. The encapsulated sand did notadversely affect the properties of the encapsulating plastic or chromicchange agents. After formation, pre-determined amounts of the finalformulations were proportioned for use in molding applications similarto those in the above example “Pressure molded optical effectthermochromic, photochromic, photo-luminescent color/shape/memorychanging plastic sheets and surface patterned items”.

EXAMPLE 17

Encased thermochromic, photochromic, and photo-luminescent lowtemperature color/shape/memory putties for impression makingapplications: A vinyl encased low temperature putty was developed as are-shapeable color changing molding pad. Low temperaturecolor/shape/memory putties were prepared as in the examples above “Lowtemperature photochromic color/shape/hardening putty composition”; “Lowtemperature thermochromic color/shape/hardening putty composition”; andLow temperature photo-luminescent color/shape/hardening puttycomposition”.

The compositions were prepared using only the Dreyco™ gum base andchromic change agent and excluded the thermoplastic Protoplast™. Theputty compositions were prepared without the thermoplastic to provide aneven lower temperature putty format (90-100° F.) than the example usingthe thermoplastic (110-120° F.). Hardened color/shape/memory puttypieces (25 gram) were placed in partially heat sealed vinyl pouches(10/1000 inch thick clear flexible vinyl stock). The pouch was sealed on3 sides. The putty was warmed, spread evenly throughout the pouch toavoid entrapped air, and then completely heat sealed into the vinylpouch laminate. The final filled pouch was flattened and cooled to roomtemperature. The final size was a flat planar configurationapproximately 3 millimeters thick and 10 by 10 centimeters squared.

Final encased putty compositions retained their thermochromicallyactive, photochromically active, or photo-luminescently activeproperties as well as the shape memory properties upon warming andcooling. Impression formation was accomplished by warming a filledsealed pouch by microwave or in warm water (100° F. for 3 minutes). Animpression resulted when the fill planar pouch was pressed by hand orwith a molding implement to create pattern. The displaced color changeputty left a clear window in the impression area. Upon cooling, theimpression area retained its molded configuration and the surroundingputty filled areas returned to their original reversible color changestate. The pieces were found to be fully re-usable and re-moldable foron-going impression making and use.

Various impression making pieces were used to create pre-determinedshapes including: animal shapes, insect shapes, faces, figures, numbers,letters, messages, pictures, diagrams, signatures, symbols, storyboards, cartoons, cartoon characters, and a variety of branded andunbranded features. Final impressions could be changed or recreatedduring play and use.

EXAMPLE 18

Encased thermochromic, photochromic, or photo-luminescent viscouscolor/shape/memory fluids and writing methods: A clear vinyl encasedviscous fluid comprising a thermochromic, photochromic, orphoto-luminescent optical effect pigment and a viscous aqueous solutionwas prepared as a writing, messaging, and activity unit. 2.5% by weightpowdered thermochromic pigment (Keystone Aniline Corporation, ChicagoIll.) was utilized for a thermochromic version. 3% by weight powderedphotochromic pigment (Color Change Corporation, Streamwood Ill.) wasutilized for a photochromic version. 10% by weight powderedphoto-luminescent pigment (Glow Incorporated, Severn Md.) was utilizedfor a glow-in-the-dark version. The viscous aqueous solution wasprepared using a concentrated solution of water titrated with highlypowdered corn starch.

Solutions containing an adjusted flowing viscous mixture of corn starchand water was admixed with powdered forms of either the thermochromicpigment, photochromic pigment or photo-luminescent pigment. Mixtureswere added to clear flexible vinyl pouches sealed on 3 sides(approximately 20 ml fluid, 10/1000 inch thick clear flexible vinyl).The pouches were purged of air and completely sealed using a standardpackaging heat sealer.

Final encased thermochromic, photochromic, and photo-luminescent viscoussolutions retained all of their optical properties respectively. Theencased solutions retained a shape-changeable pliability andmalleability when pressed or contorted. The original shape of the pouchwould slowly revert to the original planar configuration afterdistortion and left further un-perturbed. The optical change versionsprovided a convenient surface for creating and writing messages, codes,symbols and the like that could be made to appear and then dissipateover several minutes. By way of example, the photochromic-encasedversion could be conveniently written on using a 400 nanometer lightemitting diode pen light. Written matter immediately appears as the penlight passes over the encased surface. The written matter dissipateswithin 1-2 minutes or immediately by changing the shape or distortingthe pouch surface. In either case, the method and encasement completelyreverses and can be re-used systematically.

EXAMPLE 19

Color/shape/memory putty laminate coating on pre-molded plastic dollhead: Moldable coating/laminating layers comprising high temperaturethermochromic, photochromic, or photo-luminescent color/shape/hardeningputties were applied to a pre-molded plastic doll heads. The coatingswere made using color/shape/hardening putties as in the above example“High temperature thermochromic, photochromic or photo-luminescentcolor/shape/hardening putty compositions”.

A 5 inch tall plastic doll head was compression-laminated using a heatedpliable sheet of high temperature color/shape/memory putty. The sheetwas processed to 0.24 inch thick. The hot pressed sheet followed theexact contours of the doll face. Upon cooling below the meltingtransition of the putty composition, the plastic putty hardened to astiff plastic character. Upon heating with a blow dryer, hot water, orwith microwaves, the putty softens and changes color above its meltingtransition to a pliable putty like character. In the pliable state, theputty laminate can be molded, morphed, and re-contoured to a new dollface appearance. Upon cooling, the color change reverses and the puttyhardens to a final facial appearance.

EXAMPLE 20

Optical/shape/memory changing plastic coated impression forming foamsand sponges: Optical effect color/shape/memory plastic batches were madein accordance with examples above “Thermochromic color/shape/memoryplastic composition”; “Photochromic color/shape/memory plasticcomposition”; or “Photo-luminescent (glow-in-the-dark)color/shape/memory plastic composition”. Plastic sheets for formingoptical/shape/memory foams and sponges were formed as in the exampleabove “Pressure molded optical effect thermochromic, photochromic,photo-luminescent color/shape/memory changing plastic sheets and surfacepatterned items”.

Thin sheets of optical effect color/shape/memory plastic were heatlayered on to both closed and open cell foams and sponges. A firstbottom sheet was placed on a Teflon coated pan. A cut rectangular formor sponge piece was centered on the sheet. A cut second piece wasequally centered on top of the sponge piece. The sandwich was heated at300° F. for 10 minutes until the upper sheet evenly draped over thesponge and came in contact with the sheet on the bottom of the sandwich.The melted top sheet fuse with the lower sheet and was permanently pressfused to the bottom sheet to create a hermetic seal around the sponge.Excess sheet material was trimmed to yield a fully encapsulated spongeor foam piece.

At room temperature or below, the encapsulated coated foam piece wasrigid and in one colored state. When the piece was heated with warm tapwater or with warm air from a blow drier, the piece would exhibit thesponge like character of the encapsulated sponge. A variety ofimpressions, distortions, and sculptured configurations could besolidified if the piece were allowed to cool in new configuration. Allof the optical properties and effects expected of the thermochromic,photochromic and photo-luminescent pigments were preserved andcompletely reversible on thermal cycling. The shape changingreconfigurations or molded impressions were completely reversible uponre-warming of the piece. The internalized sponge or foam materialprovided an abrupt spring back to the original molded rectangular formwhen warmed.

EXAMPLE 21

General mending, fix-up, fixturing, restoration, and utilitycompositions comprised of color/shape/memory putties, and plastics:Optical effect color/shape/memory plastic batches were made inaccordance with examples above “Thermochromic color/shape/memory plasticcomposition”; “Photochromic color/shape/memory plastic composition”; or“Photo-luminescent (glow-in-the-dark) color/shape/memory plasticcomposition”. High temperature putties were made according to the aboveexample “High temperature thermochromic, photochromic orphoto-luminescent color/shape/hardening putty compositions”. Thethermochromic colorants were selected to change color at the transitiontemperatures of either the putties or plastic so that they could be usedas a safety mechanism to ensure that a user does not get scalded orburned.

Putties and plastics were used for mending, connecting, fixing, makingfixture, making holders, fitting, reinforcing, thickening, altering orotherwise augmenting household and other items that could benefit fromthe added support, strength, or related reinforcement that the itemrequired. Both the putty and plastic could be conveniently contoured andadapted to fit a particular application. The thermochromic effect wasparticularly useful to prevent burning and scalding. It was also usefulas an internal guide to provide information on working time. As thecolor started to change, the color change indicated that the workingtime was almost expired.

EXAMPLE 22

Thermochromic two part epoxy with moldable shape changing properties: Atwo component 5 minute epoxy was modified with the thermochromicbis-polydiacetylenic compound made from the diacetylenic monomerbis-2,2′-ethylene-(5,7-tetradecadiynoic acid) diamide. The diacetylenicmonomer was polymerized room temperature (ultraviolet light, 254nanometers) to a magenta color and prepared as a fine powder. Thehardening solution of a two component 5 minute epoxy (Devcon Corp.Danvers, Mass.) was colorized with 2% by weight of the polydiacetylenicpowder. The mixture became a deep magenta at room temperature. Thethermochromically colorized hardening component remained stable undernormal conditions for prolonged periods (more than 1 year).

A color/shape/memory epoxy plastic was made by mixing from 25% of thecolorized hardening component to up to 50% of the colorized hardeningcomponent to from 75% of the epoxy component to 50% of the epoxycomponent respectively. Softer more temperature sensitive shape changingplastics were made with compositions less than 50% hardening component.In all cases, the epoxy mixtures cured within 5 to 10 minutes. Thethermochromic material indicated elevated temperatures during the curingstep and immediately after mixing due the exothermic reaction. Thethermochromic material exhibited its brightest coloration to an orangeyellow immediately prior to the 5 minute time frame indicating that theepoxy was about to set and that the working time had less than 30seconds left prior to stiffening. The set thermochromic epoxy exhibitedgood color and shape change characteristic upon reversible heating andcooling cycles.

EXAMPLE 23

Printed thermochromic color/shape/memory plastic die cut toy piecesincluding strips, rods, laces, tiles, and die cut shapes and figures: Ashape changing plastic composition with combined shape memory propertiesand reversible thermochromic printed matter was formulated using athermoplastic polyurethane (Rohm and Haas Corp., Philadelphia, Pa.).Images, messages, symbols, characters, cartoon characters, figures,graphics and printed information was screen printed using al 80 meshsilk screen and ultraviolet light curable thermochromic inks (MatsuiInternational Inc., Gardena, Calif.).

0.01, 0.02, 0.03, 0.04, 0.06, 0.08, 0.1 and 0.2 inch thick shapechangeable plastic sheets were prepared as in the above examples“Thermochromic color/shape/memory plastic composition” and “Pressuremolded optical effect thermochromic, photochromic, photo-luminescentcolor/shape/memory changing plastic sheets and surface patterned items”.Flat 12 inch by 12 inch sheets were screen printed using thermochromicultraviolet light cured inks and a 1200 watt per inch square mediumpressure mercury vapor lamp for curing. A variety of image types wereprinted using both low temperature (10° C., 15° C., and 20° C.reversible thermochromic inks) or higher temperature version (25° C.,27° C., 29° C., 31° C., 35° C., 37° C. and higher reversiblethermochromic inks). The printed sheets/images retained full shape andcolor change characteristics of the full ranges expected.

EXAMPLE 24

Color/shape/memory plastics for moldable items including: toothbrush tiestrings/hooks, toy connectors, picture stands, hair bands, plasticutensils, foldable cups and plates: Optical effect color/shape/memoryplastic batches were made in accordance with examples above“Thermochromic color/shape/memory plastic composition”; “Photochromiccolor/shape/memory plastic composition”; or “Photo-luminescent(glow-in-the-dark) color/shape/memory plastic composition”. Thethermoplastic urethanes were utilized (Rohm and Haas Corp.,Philadelphia, Pa. or Noveon Corporation, Cleveland Ohio). Thermochromicand photo-chromic could be used from various sources (Color ChangeCorporation, Streamwood Ill., Keystone Aniline Corporation, ChicagoIll., B&H Colour Change Limited, London England).

Molding was accomplished using methods described in the above example“Direct pressure molded optical effect thermochromic, photochromic,photo-luminescent color/shape/memory changing plastic structures”.Processed shapes were die cut and/or trimmed. The initial moldedconfigurations were set to appear as standard items. The contortedtransient shapes could be pre-set prior at the factory prior to releaseand sale of the product or by a purchaser or user of the product duringusage. To pre-set a new shape, the molded item was warmed, contorted andthen chilled. The pre-set configuration would be sustained until theitem was warmed again and allowed to re-achieve its original moldedconfiguration. All of the thermochromic, photochromic or other color andshape change reversible properties of the molded pieces were maintained.

EXAMPLE 25

Thermochromic, photochromic, photo-luminescent/shape changing pencilsand pens: Optical effect color/shape/memory plastic batches were made inaccordance with examples above “Thermochromic color/shape/memory plasticcomposition”; “Photochromic color/shape/memory plastic composition”; or“Photo-luminescent (glow-in-the-dark) color/shape/memory plasticcomposition”. The thermoplastic urethanes were utilized (Rohm and HaasCorp., Philadelphia, Pa. or Noveon Corporation, Cleveland Ohio).Thermochromic and photo-chromic could be used from various sources(Color Change Corporation, Streamwood Ill., Keystone AnilineCorporation, Chicago Ill., B&H Colour Change Limited, London England).Flexible pencil lead graphite was used for the color/shape and memorypencil. Normal ball point pen plastic inserts were used forcolor/shape/memory change pens.

Tubular extruded rods of optical effect color/shape/memory changingplastic were formed using standard extruding means. Inner diameter boreswere made to match the flexible pencil lead and ink pen insert diameters(2 millimeters and 3 millimeters respectively). Outer diameters for thewhole rods were kept at 6 millimeters. The pencil was assembled byinsertion of the flexible lead into the hollowed plastic tube, additionof a metal crimp to hold an eraser and final heated compression forfinishing. The pen was assembled by threading a metal holder forattaching the ball point insert and placing a vented cap on the end ofthe pen barrel. In both cases, assembled pens and pencils exhibited allof the expected color, shape and memory properties of the formulatedcolor/shape/memory plastics prepared. Both the pens and pencils could bewarmed, contorted and frozen into positions of interest. A commensuratecolor change accompanied the shape change.

EXAMPLE 25

Multiple response color/shape/memory change element that exhibits asimultaneous or sequential color and shape change in response toelevated cooking temperatures: A cooking device was developed forsimultaneously reporting a cooking temperature through a thermochromiccolor and thermally induced shape change. A thermoplastic compositionwas prepared whereby a base nylon material was compounded at 25% withthe thermoplastic shape-change material Estane™ 5778. A high-temperaturereversible thermochromic dye was prepared and compounded into theplastic composition.

The composition was molded into a planar sliced disc configuration. Uponthermal heating the disc blades were folded upward to create an enclosedcavity. The composition was set in the closed cavity configuration. Uponheating and temperature monitoring, the comprising composition exhibitedboth thermochromic reversibility and shape change characteristics afterexposure to elevated temperatures for 1 hour (300° F.). The dual effectof color and shape change provided a convenient method for visuallyidentifying when a temperature had been achieved. The dual affect of acolor and shape change provided a confident confirmation method forvalidating that a temperature had been achieved.

EXAMPLE 26

A soft color/shape/memory change thermoplastic putty based advanceddental night guard device: A thermoplastic mixture comprising 33% byweight Protoplast™ (WRF Aquaplast Crop.), 66.8% by weight polyvinylacetate Evatane™ 33-400 (Atofina Chemicals, Inc. Philadelphia, Pa.), and0.2% by weight of the Thermochromic bis-polydiacetylenic compound madefrom the diacetylenic monomer bis-2,2′-ethylene-(6,8-nonadecadiynoicacid) diamide. The diacetylenic monomer was polymerized room temperature(ultraviolet light, 254 nanometers) to a deep blue color and prepared asa fine powder. Initially the thermoplastic composition was warmed to200° F. and blended. After blending and cooling to 160° F., thethermochromic bis-polydiacetylene was added in a powder form and mixedto uniformity. The color/shape/memory composite exhibited good dentalimpression forming properties at elevated temperatures (150-155° F.) aswell as thermochromic indication that the material had adequately softenas indicated by the integrated thermochromic agent.

Dental trays were thermoformed using 30/1000, 40/1000, 50/1000, or60/1000 in thick thermoformable plastics. An upper jaw mold was made tomatch a medium bite. Polyvinyl chloride, polycarbonate, high densitypolypropylene, and Delrin™ were utilized as tray forming plastics. Slimtray designs were used (0.25 inch deep). The thermoplasticcolor/shape/memory composition was warmed to 160° F. by microwave andfilled into the tray to a complete depth. Filled trays were allowed tocool to room temperature prior to use. The thermochromic materialclosely matched the softening temperature. The device turns a deep redwhen ready. Bright orange indicated that the material is too hot. Purpleindicated setting/cooling and blue indicated complete set.

For use, a pan of water was heated to 155° F. Place a sample plastictray down (thermal material up). The piece will turn from a purple hueto a deep red and then red at about the 1 minute mark. At 1 minute, thepiece was immediately removed from the hot water in order to make adental impression. Only a light to medium bite is required. Settingrequired holding the piece in the mouth 2-3 minutes. 3 mouthfuls of cooltap water were exchanged during the setting period. The sample could beremolded and could be re-used multiple times. The final formed trayexhibited good cushioning characteristics.

EXAMPLE 27

A medium soft color/shape/memory change thermoplastic putty basedadvanced dental night guard device: A thermoplastic mixture comprising49% by weight Protoplast™ (WRF Aquaplast Crop.), 49% by weight polyvinylacetate Evatane™ 33-400 (Atofina Chemicals, Inc. Philadelphia, Pa.), and2% by weight of the thermochromic colorant (60° C. reversiblethermochromic pigment, B&H Colour Change Limited, London England).Initially the thermoplastic composition was warmed to 200° F. andblended. After blending and cooling to 160° F., the thermochromicpigment was added in a powder form and mixed to uniformity. Thecolor/shape/memory composite exhibited good dental impression formingproperties at elevated temperatures (150-155° F.) as well asthermochromic indication that the material had adequately softened asindicated by the integrated thermochromic agent.

Dental trays were thermoformed using 30/1000, 40/1000, 50/1000, or60/1000 in thick thermoformable plastics. An upper jaw mold was made tomatch a medium bite. Polyvinyl chloride, polycarbonate, high densitypolypropylene, and Delrin™ were utilized as tray forming plastics. Slimtray designs were used (0.25 inch deep). The thermoplasticcolor/shape/memory composition was warmed to 160° F. by microwave andfilled into the tray to a complete depth. Filled trays were allowed tocool to room temperature prior to use. The thermochromic materialclosely matched the softening temperature. The device turns a deep redwhen ready. Bright orange indicated that the material is too hot. Purpleindicated setting/cooling and blue indicated complete set.

For use, a pan of water was heated to 155° F. Place a sample plastictray down (thermal material up). The piece will turned from a deep bluehue to a bright off-white hue at 1 minute, the piece was immediatelyremoved from the hot water in order to make a dental impression. Only alight to medium bite is required. Setting required holding the piece inthe mouth 2-3 minutes. 3 mouthfuls of cool tap water were exchangedduring the setting period. The sample could be remolded and re-usedmultiple times. The final formed tray exhibited good cushioningcharacteristics and a medium stiffness.

EXAMPLE 28

A stiff color/shape/memory change thermoplastic putty based advanceddental night guard device: A thermoplastic mixture 66% by weightProtoplast™ (WRF Aquaplast Crop.), 32% by weight polyvinyl acetateEvatane™ 33-400 (Atofina Chemicals, Inc. Philadelphia, Pa.), and 2% byweight of the thermochromic colorant (60° C. reversible thermochromicpigment, B&H Colour Change Limited, London England). Initially thethermoplastic composition was warmed to 200° F. and blended. Afterblending and cooling to 160° F., the thermochromic pigment was added ina powder form and mixed to uniformity. The color/shape/memory compositeexhibited good dental impression forming properties at elevatedtemperatures (150-155° F.) as well as thermochromic indication that thematerial had adequately softened as indicated by the integratedthermochromic agent.

Dental trays were thermoformed using 30/1000, 40/1000, 50/1000, or60/1000 in thick thermoformable plastics. An upper jaw mold was made tomatch a medium bite. Polyvinyl chloride, polycarbonate, high densitypolypropylene, and Delrin™ were utilized as tray forming plastics. Slimtray designs were used (0.25 inch deep). The thermoplasticcolor/shape/memory composition was warmed to 160° F. by microwave andfilled into the tray to a complete depth. Fill trays were allowed tocool to room temperature prior to use. The thermochromic materialclosely matched the softening temperature. The device turns a deep redwhen ready. Bright orange indicated that the material is too hot. Purpleindicated setting/cooling and blue indicated complete set.

For use, a pan of water was heated to 155° F. Place a sample plastictray down (thermal material up). The piece will turn from a deep bluehue to a bright off-white hue at 1 minute, the piece was immediatelyremoved from the hot water in order to make a dental impression. Only alight to medium bite is required. Setting required holding the piece inthe mouth 2-3 minutes. 3 mouthfuls of cool tap water were exchangedduring the setting period. The sample could be remolded and re-usedmultiple times. The final formed tray exhibited good cushioningcharacteristics and a medium stiffness.

EXAMPLE 29

Shape and color change element cooking thermometers: An insertablecooking thermometer with a pre-indicating shape change initially tells acook that cooking is in progress. When the shape change has occurred,the cook is alerted to remove the thermometer within a specified time totell precisely when cooking is near completion. The thermometer isfurther equipped with a color change element that indicates the exactlevel of doneness of the food type being cooked.

The thermometer can be molded with a convenient shape memory plasticthat undergoes a shape change from a pre-set condition back to itsoriginal molded position. The composition comprising the molded piecewill be determined by the duration of exposure to elevated temperaturesfor specified periods of time. By way of example, compositions find usethat can hold a particular shape for a period of 30, 60, or 90 minutesat temperatures in the range of 300° F. to 450° F. The molded shape canbe reshaped at elevated temperature and rapidly chilled to possess adistorted transient shape at room temperature and temperatures below thedesired cooking temperature. Upon heating for a specified time andtemperature, the pre-set distorted shape reverts to its original moldedshape. The reversion can be designed to occur prior to cookingcompletion so that the shape change event can be used as a pre-indicatorthat cooking is in progress, but not compete.

Upon complete reversion of the shape change form the distorted pre-setshape to the original molded shape, the cook is alerted to utilize thethermometer for determining more precisely when cooking is complete. Thethermometer may contain a temperature specified thermochromic agent atits distal to the shape-changing end. The device therefore would possessone end that is the shape changing pre-indicator for doneness and theother end that has a precise temperature sensing color change elementthat tells the exact level of doneness.

For use, the thermometer is inserted into a food type to be cooked priorto cooking. The insertion end possesses the thermochromic materialnecessary to determine exact doneness of the food type. The device isretained in the food type during cooking. As cooking proceeds, and at aspecified time prior to completion of cooking, the shape change endsticking out of the food type will visually change shape. When the shapechange becomes apparent, the device can be used as a thermometer bypulling it out of the food being cooked. If cooking is complete at theinitial point of pulling the thermometer out of the food, the colorchange will be apparent. If the food is not yet cooked, the color changeindicate incomplete cooking. The thermometer end can be reinserted intothe same position so that cooking can be checked again. Cooks cancontinue to check doneness until the color change and cooking arecomplete.

Other applications:

Assorted other examples can include, but are not limited to: customizedputty toothbrush holders, custom body armor items, custom fingerpositioning device for pencils and pens; and/or thermochromiccolor/shape/memory outdoor play toys for beach, sand, and backyard playand activities; make and play sets including animal, people, insect,flower, construction, skeletal, cooking, jewelry, and assorted play setsusing color/shape/memory plastic pieces: universal connectors forvarious toys and house-hold applications; 3-D puzzles pieces made withcolor/shape/memory plastic; interactive color/shape/memory plasticpackaging and demonstration; simultaneous dual temperature responseautomotive child safety; collapsing water containers, liquid containers,re-usable collapsible/shapeable storage containers as well as assortedother products and items that would benefit from multiple simultaneousor sequential optical, color, and shape changing elements.

The subject invention provides for a number of advantages, including thefollowing.

Plural compositions possessing multiple enabling elements of opticalchange, color change, shape change, shape memory, and state change findwide variety of utility applications, entertainment applications,learning applications, educational applications, orthopedic application,construction applications, home-building applications, packagingapplications, play applications including, but not limited to: “make andplay” kits, toys, action figures, dolls, doll accessories, doll hairattachments, doll hair that can be rooted, games, puzzles, connectorsthat interface with existing or other future products, jewelry, arts andcraft kits, construction kits, building kits, mending kits, ashouse-hold items, as retail items, a packaging items, display andpromotional items, body armor, prosthetics and prosthetic deviceaccessories, athletic equipment such as skies, balls and other sportingitems, hardware usages, braces, mouth pieces, mouth guards, adhesives,footwear, clothing, multi-response temperature monitoring for a varietyof applications including cooking and reporting doneness, and as a rangeof other consumer, military, industrial, and commercial products.

Shape or color change alone has been noted as interesting, butsignificantly less than the “magic” of novel materials that contain bothproperties of color and shape change together. Children have expressedinterest in simple and complex shapes and objects made withcolor/shape/memory compositions. Simultaneous color and shape or coloror shape changes that lead each other are of interest. Play patternsusing color/shape/memory compositions can be done individually or as agroup by passing shape along and changing it from child to child. Avariety of new games are made possible. The final color andcorresponding shape change should be dramatic and in a temperaturerange. Whereas children like the simple pieces, they express interest incomplete toys made out of the color/shape/memory material. Boys andgirls both express equal interest, but different desired play patterns,toys and play items based on color/shape/memory compositions can bedesigned for either young children and infants or up to teenagers andyoung adults. Schools and learning centers can find use for learningtoys and items comprising color/shape/memory materials.

Multi-optical color/shape/memory compositions can take on a range ofcharacteristics that may be desirable for particular applications. Theycan have purely plastic-like characteristics, purely putty-likecharacteristics, or a hybrid of the characteristics within the samecomposition. A market application of interest, processing traits, costconsiderations and product specifications will dictate which enablingelements and physical characteristics will be utilized in the finalcomposition comprising an item to be produced.

As such, the invention represents a significant contribution to the art.

While the present invention has been described with reference to thespecific embodiments thereof, it should be understood by those skilledin the art that various changes may be made and equivalents may besubstituted without departing from the true spirit and scope of theinvention. In addition, many modifications may be made to adapt aparticular situation, material, composition of matter, process, processstep or steps, to the objective, spirit and scope of the presentinvention. All such modifications are intended to be within the scope ofthe claims appended hereto.

What is claimed is:
 1. A composite material comprising: (a) a shapechange component that changes shape in response to a first appliedstimulus; and (b) an optical change component that changes an opticalproperty in response to a second applied stimulus.
 2. The compositematerial according to claim 1, wherein said shape change component is ashape memory component.
 3. The composite material according to claim 1,wherein optical change component is a chromic change component.
 4. Thecomposite material according to claim 1, said first applied stimulus isa temperature change.
 5. The composite material according to claim 1,wherein said first applied stimulus is a light change.
 6. The compositematerial according to claim 1, wherein said second applied stimulus is atemperature change.
 7. The composite material according to claim 1,wherein said second applied stimulus is a light change.
 8. The compositematerial according to claim 1, wherein said first applied stimulus andsecond applied stimulus are the same.
 9. The composite materialaccording to claim 1, wherein said first applied stimulus and secondapplied stimulus are different.
 10. The composite material according toclaim 1, wherein said composite material undergoes a shape and opticalchange simultaneously.
 11. The composite material according to claim 1,wherein said composite material undergoes a shape and optical changesequentially.
 12. The composite material according to claim 1, whereinsaid composite material is a plastic.
 13. The composite materialaccording to claim 12, wherein said shape change and optical changecomponents are comolded.
 14. The composite material according to claim12, wherein said optical change component is positioned on at least onesurface of said shape change component.
 15. The composite materialaccording to claim 1, wherein said composite material is a putty. 16.The composite material according to claim 1, wherein said compositematerial comprises at least one additional component.
 17. The compositematerial according to claim 16, wherein said at least one additionalcomponent modifies the properts of said material.
 18. The compositematerial according to claim 16, wherein said at least one additionalcomponent is an inert filler.
 19. A toy comprising a composite materialaccording to claim
 1. 20. The toy according to claim 19, wherein saidtoy is a bath toy.
 21. The toy according to claim 19, wherein said toycomprises a play set.
 22. The toy according to claim 19, wherein saidtoy comprises a play piece.
 23. The toy according to claim 19, whereinsaid toy is a doll.
 24. The toy according to claim 20, wherein said dollcomprises hair that comprises said composite material.
 25. A cookingutensil comprising a composite material according to claim
 1. 26. Thecooking utensil according to claim 25, wherein said utensil is a cookingindicator.
 27. A writing element comprising a composite materialaccording to claim
 1. 28. An dental device comprising a compositematerial according to claim
 1. 29. A method comprising: contacting: (a)a shape change component that changes shape in response to a firstapplied stimulus; and (b) an optical change component that changes anoptical property in response to a second applied stimulus; with eachother to produce a composite material.